Long-term efficacy and safety of a permeation-enhanced testosterone transdermal system in hypogonadal men

Biotransformation of anabolic androgenic steroids in human skin cells

In comparison to well-known drug-metabolizing organs such as the liver, the metabolic capacity of human skin is still not well elucidated despite the widespread use of topical drug application. To gain a comprehensive insight into anabolic steroid metabolism in the skin, six structurally related anabolic androgenic steroids, testosterone, metandienone, methyltestosterone, clostebol, dehydrochloromethyltestosterone, and methylclostebol, were applied to human keratinocytes and fibroblasts derived from the juvenile foreskin. Phase I metabolites obtained from incubation media were analyzed by gas chromatography-mass spectrometry. The 5α-reductase activity was predominant in the metabolic pathways as supported by the detection of 5α-reduced metabolites after incubation of testosterone, methyltestosterone, clostebol, and methylclostebol. Additionally, the stereochemistry structures of fully reduced metabolites (4α,5α-isomers) of clostebol and methylclostebol were newly confirmed in this study by the help of inhouse synthesized reference materials. The results provide insights into the steroid metabolism in human skin cells with respect to the characteristics of the chemical structures.

Pharmacokinetics of testosterone therapies in relation to diurnal variation of serum testosterone levels as men age

Background

To improve symptoms associated with testosterone deficiency, many testosterone therapies are available that aim to restore serum testosterone (T) levels to the normal physiologic range. The magnitude, frequency, and duration between peak and trough T concentrations vary with route of administration, and none reflect normal endogenous daily diurnal T variations.

Objective

To compare pharmacokinetic profiles of serum T from approved T formulations with endogenous diurnal T variations in young and older men, and to consider whether there may be value in mimicking the diurnal T rhythmicity with exogenous testosterone therapies as men age.

Materials and methods

A literature search of studies examining the diurnal variation of endogenous T in healthy men and men with testosterone deficiency was performed using PubMed in January 2020. Additional searches for serum T pharmacokinetic profiles of various testosterone therapy formulations were also conducted. Prescribing information for various T formulations was also reviewed.

Discussion and conclusion

Endogenous diurnal T variation is well described and appears to be blunted naturally as men age. Men with testosterone deficiency lack diurnal T variation and exhibit a flatter T profile compared with eugonadal men. Some T replacement options provide intraday T level variations similar to normal circadian secretion, and others provide a flatter exposure profile reflective of depot release. Others provide profiles that exceed the frequency and physiologic range of the natural diurnal variation of T. All exogenous T replacement dosing targets an increase in average T levels to within the normal physiologic range and improves symptoms associated with low T, but no single testosterone therapy can exactly mimic the normal diurnal T patterns seen in younger men and the blunted circadian T secretion of older men.

Preventing secondary exposure to women from men applying a novel nestorone/testosterone contraceptive gel

BACKGROUND

Testosterone (T)/Nestorone (NES) combination gel is a potential transdermal male contraceptive that suppresses gonadotropins and spermatogenesis. Transfer of transdermal T from men to women can be prevented by washing or covering application sites with clothing.

OBJECTIVES

We hypothesized that showering or wearing a shirt over gel application sites would prevent secondary exposure of T and NES to a woman after close skin contact.

MATERIALS AND METHODS

Twelve healthy male and 12 healthy female participants were recruited. Men applied T/NES 62 mg/8 mg gel to their shoulders and upper arms. Two hours after application, female partners rubbed the application site for 15 min. Exposure in the female partner was assessed under three conditions: a shirt covered the application site; the man showered prior to skin contact; or without intervention to reduce transfer. Serum T and NES concentrations were measured by LC-MS/MS in serial blood samples for 24 h after gel exposure.

MAIN OUTCOMES

Change in female serum T and NES levels as measured by average concentration over 24 h (C_avg ).

RESULTS

Median female serum T C_avg was 23.9 ng/dL (interquartile range, 19.3, 33.9) with the shirt barrier and 26.7 ng/dL (20.7, 33.9) after showering, which was higher than baseline 20.9 ng/dL (16.7, 25.0), both p < 0.03) but lower than without intervention (58.2 ng/dL [30.9, 89.1], both p < 0.01). Female serum NES C_avg and maximum concentration were below the lower limit of quantification with the shirt barrier and after showering, but increased without intervention in six of 12 women (maximum concentration <60 pg/mL). Men had lower average serum NES levels after showering (47 pg/ml [20, 94] compared to no intervention (153.3 pg/mL [51, 241], p < 0.02).

CONCLUSION

Secondary transfer of T and NES occurs after intensive skin contact with the gel application site. Secondary transfer is decreased by a shirt barrier or showering before contact.

Cardiovascular risks and elevation of serum DHT vary by route of testosterone administration: a systematic review and meta-analysis

BACKGROUND

Potential cardiovascular (CV) risks of testosterone replacement therapy (TRT) are currently a topic of intense interest. However, no studies have addressed CV risk as a function of the route of administration of TRT.

METHODS

Two meta-analyses were conducted, one of CV adverse events (AEs) in 35 randomized controlled trials (RCTs) of TRT lasting 12 weeks or more, and one of 32 studies reporting the effect of TRT on serum testosterone and dihydrotestosterone (DHT).

RESULTS

CV risks of TRT: Of 2,313 studies identified, 35 were eligible and included 3,703 mostly older men who experienced 218 CV-related AEs. No significant risk for CV AEs was present when all TRT administration routes were grouped (relative risk (RR) = 1.28, 95% confidence interval (CI): 0.76 to 2.13, P = 0.34). When analyzed separately, oral TRT produced significant CV risk (RR = 2.20, 95% CI: 1.45 to 3.55, P = 0.015), while neither intramuscular (RR = 0.66, 95% CI: 0.28 to 1.56, P = 0.32) nor transdermal (gel or patch) TRT (RR = 1.27, 95% CI: 0.62 to 2.62, P = 0.48) significantly altered CV risk. Serum testosterone/DHT following TRT: Of 419 studies identified, 32 were eligible which included 1,152 men receiving TRT. No significant difference in the elevation of serum testosterone was present between intramuscular or transdermal TRT. However, transdermal TRT elevated serum DHT (5.46-fold, 95% CI: 4.51 to 6.60) to a greater magnitude than intramuscular TRT (2.20-fold, 95% CI: 1.74 to 2.77).

CONCLUSIONS

Oral TRT produces significant CV risk. While no significant effects on CV risk were observed with either injected or transdermal TRT, the point estimates suggest that further research is needed to establish whether administration by these routes is protective or detrimental, respectively. Differences in the degree to which serum DHT is elevated may underlie the varying CV risk by TRT administration route, as elevated serum dihydrotestosterone has been shown to be associated with CV risk in observational studies.

Application site affects the pharmacokinetics of topical testosterone applied to the axilla compared with the inner arm

PURPOSE

This study compared the pharmacokinetics of a single dose of 1% testosterone solution after application to the inner arm or the axilla as application sites for transdermal testosterone therapy.

METHODS

Healthy, not pregnant, premenopausal women, 18 to 45 years of age with a body mass index of 20 to 28 kg/m(2) were enrolled into a single-center, open-label, randomized, 2-way crossover study. Serum total testosterone (TT), free testosterone (fT), and sex hormone binding globulin concentrations were measured. Pharmacokinetic parameters determined from serum TT and fT included area under the serum concentration versus time curve from time zero (pre-dose) until 72 hours post-dose (AUC0-72), Cmax, and Tmax. Descriptive statistics were performed on serum concentrations of TT and fT for each site. ANOVA was performed on AUC0-72 and Cmax.

FINDINGS

A single-dose application of 1% testosterone solution to the inner arm and the axilla produced clear increases in TT and fT. Slower and lower increases in TT and fT were observed after treatment to the inner arm. Based on baseline-corrected AUC versus time curves, the bioavailability of 1% testosterone solution was increased 2-fold for the axilla compared with the inner arm.

IMPLICATIONS

The absorption of a 1% testosterone solution was significantly greater after application to the axilla than to the inner arm. Study number DDS16; Australian Therapeutic Goods Administration, CTN 2005/158.

An update on male hypogonadism therapy

INTRODUCTION

Men who have symptoms associated with persistently low serum total testosterone level should be assessed for testosterone replacement therapy.

AREAS COVERED

Acute and chronic illnesses are associated with low serum testosterone and these should be recognized and treated. Once the diagnosis of male hypogonadism is made, the benefits of testosterone treatment usually outweigh the risks. Without contraindications, the patient should be offered testosterone replacement therapy. The options of testosterone delivery systems (injections, transdermal patches/gels, buccal tablets, capsules and implants) have increased in the last decade. Testosterone improves symptoms and signs of hypogonadism such as sexual function and energy, increases bone density and lean mass and decreases visceral adiposity. In men who desire fertility and who have secondary hypogonadism, testosterone can be withdrawn and the patients can be placed on gonadotropins. New modified designer androgens and selective androgen receptor modulators have been in preclinical and clinical trials for some time. None of these have been assessed for the treatment of male hypogonadism.

EXPERT OPINION

Despite the lack of prospective long-term data from randomized, controlled clinical trials of testosterone treatment on prostate health and cardiovascular disease risk, the available evidence suggests that testosterone therapy should be offered to symptomatic hypogonadal men.

Male hypogonadism

Male hypogonadism is a clinical syndrome that results from failure to produce physiological concentrations of testosterone, normal amounts of sperm, or both. Hypogonadism may arise from testicular disease (primary hypogonadism) or dysfunction of the hypothalamic-pituitary unit (secondary hypogonadism). Clinical presentations vary dependent on the time of onset of androgen deficiency, whether the defect is in testosterone production or spermatogenesis, associated genetic factors, or history of androgen therapy. The clinical diagnosis of hypogonadism is made on the basis of signs and symptoms consistent with androgen deficiency and low morning testosterone concentrations in serum on multiple occasions. Several testosterone-replacement therapies are approved for treatment and should be selected according to the patient's preference, cost, availability, and formulation-specific properties. Contraindications to testosterone-replacement therapy include prostate and breast cancers, uncontrolled congestive heart failure, severe lower-urinary-tract symptoms, and erythrocytosis. Treatment should be monitored for benefits and adverse effects.

Hypogonadism in the aging male diagnosis, potential benefits, and risks of testosterone replacement therapy

Hypogonadism in older men is a syndrome characterized by low serum testosterone levels and clinical symptoms often seen in hypogonadal men of younger age. These symptoms include decreased libido, erectile dysfunction, decreased vitality, decreased muscle mass, increased adiposity, depressed mood, osteopenia, and osteoporosis. Hypogonadism is a common disorder in aging men with a significant percentage of men over 60 years of age having serum testosterone levels below the lower limits of young male adults. There are a variety of testosterone formulations available for treatment of hypogonadism. Data from many small studies indicate that testosterone therapy offers several potential benefits to older hypogonadal men. A large multicenter NIH supported double blind, placebo controlled study is ongoing, and this study should greatly enhance the information available on efficacy and side effects of treatment. While safety data is available across many age groups, there are still unresolved concerns associated with testosterone therapy. We have reviewed the diagnostic methods as well as benefits and risks of testosterone replacement therapy for hypogonadism in aging men.

Efficacy and safety of the 2% formulation of testosterone topical solution applied to the axillae in androgen-deficient men

OBJECTIVES

Testosterone replacement therapy in hypogonadal men relieves symptoms and restores serum testosterone levels to the physiological range. In this study, we assessed the safety, pharmacokinetics, and efficacy of the 2% formulation of testosterone topical solution applied daily to the axillae.

DESIGN AND PATIENTS

An open-label trial was conducted in testosterone-deficient men who started on a daily dose of 60 mg of testosterone. Dose was adjusted on Days 45 and 90 when necessary to maintain serum testosterone levels within the physiological range (10·41-36·44 nmol/l) based on average serum testosterone levels on Days 15 and 60, respectively. Sexual function and mood changes were assessed by the Psychosexual Daily Questionnaire (PDQ) for the 7 days preceding visits at Days 1, 15, 60, and 120; and quality of life by SF-36 questionnaire on Days 1, 60, and 120. Safety parameters, laboratory tests, and adverse events were collected at each visit.

RESULTS

Among the Completer Set (135 study completers and 3 patients who discontinued due to adverse events), 76·1% (Days 15/16), 84·8% (Days 60/61), and 84·1% (Days 120/121) had an average total testosterone level between 10·41-36·44 nmol/l. PDQ scores increased significantly from baseline to 120 days of treatment (p < 0·0001). Significant improvement was observed in the physical (p < 0·05) and mental (p < 0·0001) components of the SF-36 after 120 days of treatment. Adverse events reported in >2% of the 155 subjects who received ≥ 1 dose were application site irritation (7·1%), application site erythema (5·2%), headache (5·2%), increased hematocrit (3.9%), nasopharyngitis (3·9%), diarrhea (2·6%), and vomiting (2·6%).

CONCLUSIONS

These results indicate that once-daily application of the testosterone topical solution 2% to the axillae is a safe and effective treatment for androgen replacement in hypogonadal men.

A practical guide to male hypogonadism in the primary care setting

There is a high prevalence of hypogonadism in the older adult male population and the proportion of older men in the population is projected to rise in the future. As hypogonadism increases with age and is significantly associated with various comorbidities such as obesity, type 2 diabetes, hypertension, osteoporosis and metabolic syndrome, the physician is increasingly likely to have to treat hypogonadism in the clinic. The main symptoms of hypogonadism are reduced libido/erectile dysfunction, reduced muscle mass and strength, increased adiposity, osteoporosis/low bone mass, depressed mood and fatigue. Diagnosis of the condition requires the presence of low serum testosterone levels and the presence of hypogonadal symptoms. There are a number of formulations available for testosterone therapy including intramuscular injections, transdermal patches, transdermal gels, buccal patches and subcutaneous pellets. These are efficacious in establishing eugonadal testosterone levels in the blood and relieving symptoms. Restoration of testosterone levels to the normal range improves libido, sexual function, and mood; reduces fat body mass; increases lean body mass; and improves bone mineral density. Testosterone treatment is contraindicated in subjects with prostate cancer or benign prostate hyperplasia and risks of treatment are perceived to be high by many physicians. These risks, however, are often exaggerated and should not outweigh the benefits of testosterone treatment.

Comparison of oral versus transdermal testosterone supplementation in hypogonadal men

: To compare mean serum total testosterone, bioavailable-testosterone, and dihydrotestosterone levels between transdermal testosterone and oral testosterone undecanoate treatment.

: Multicentre, randomized, cross-over study; 44 men >18 years, testosterone ≤2.5 ng/mL. Two patches (Testopatch

: Mean age 49 years. Mean testosterone before inclusion 1.99 ng/mL. Mean testosterone serum levels over the last 48 h of Testopatch treatment were superior to Pantestone (4.64 vs. 2.58 ng/mL, p<0.001). Testosterone trough levels at the end of each treatment period were significantly higher for Testopatch (3.15 vs. 2.45 ng/mL, p<0.01). Bioavailable-testosterone levels over the first and last 48 h of treatment were significantly greater with Testopatch than with Pantestone (p=0.001 and p<0.01). Dihydrotestosterone levels over the first and last 48 h of treatment (0.71 vs. 1.05 ng/mL and 0.68 vs. 0.89 ng/mL) as well as at trough (0.59 vs. 0.96 ng/mL) were significantly lower with Testopatch than with Pantestone (p<0.001, p<0.05, and p<0.001). SHBG levels decreased by Pantestone but not by Testopatch (p<0.001).

: Testopatch was superior to Pantestone to increase testosterone and bioavailable-testosterone levels in hypogonadal men from the first days and throughout the three weeks of treatment. Pantestone increased dihydrotestosterone to a larger extent and decreased SHBG.

Testosterone treatment in elderly men

Testosterone has been used in testicular and hypothalamo-pituitary diseases since the 1940s. There is growing interest in the use of testosterone in aging men, and this has stimulated research into the benefits of male hormone replacement. Testosterone treatment of men with hypogonadism might have beneficial effects on body composition, muscle strength, sexual function, and cognition. There are several modes of administration of the male hormone, with injectable testosterone esters and implanted testosterone pellets being the mainstay of treatment until recently. These preparations are increasingly being replaced by transdermal patches, gels, and long-acting parenteral preparations. Testosterone patches and gels are ideally for elderly men. Treatment with the male hormone is relatively safe, if patients are selected appropriately and monitored carefully. The most important adverse effects are on the prostate. In this review, we briefly discuss the indications, contraindications, and benefits of testosterone treatment. Further, we list the adverse effects, advantages, and disadvantages of various testosterone preparations in elderly men.

Testosterone therapy in hypogonadal men and potential prostate cancer risk: a systematic review

This paper provides a systematic review of the literature about prostate cancer risk associated with testosterone therapy for hypogonadism. A comprehensive search of MEDLINE, EMBASE and other resources was conducted to identify articles that highlight occurrences of prostate cancer in men receiving testosterone therapy for hypogonadism treatment. Articles that met study inclusion criteria were assessed for causality between testosterone treatment and prostate cancer, increased prostate-specific antigen or abnormal digital rectal examination findings. Of 197 articles relating to testosterone therapy, 44 met inclusion criteria: 11 placebo-controlled, randomized studies; 29 non-placebo-controlled studies of men with no prostate cancer history; and 4 studies of hypogonadal men with history of prostate cancer. Of studies that met inclusion criteria, none demonstrated that testosterone therapy for hypogonadism increased prostate cancer risk or increased Gleason grade of cancer detected in treated vs untreated men. Testosterone therapy did not have a consistent effect on prostate-specific antigen levels.

Hypopituitarism: clinical features, diagnosis, and management

Hypopituitarism is characterized by loss of function of the anterior pituitary gland. It is a rare condition that can present at any age and is caused by pathology of the hypothalamic-pituitary axis or one of many gene mutations. The symptoms and signs of hypopituitarism may evolve over several years and be nonspecific or related to the effects of the underlying disease process or to hormone deficiencies. Investigation of patients requires a combination of basal hormone levels and dynamic function tests; management requires regular monitoring. The goal of physicians managing patients who have hypopituitarism is to improve their health and long-term outcome.

Testosterone therapy in the aging male

The decline, with aging, in serum concentrations of biologically active forms of testosterone in men is an indisputable fact and some men will eventually develop symptoms of late-onset hypogonadism (LOH) with its clinical consequences. LOH reduces quality of life and may pose important risk factors for frailty, changes in body composition, cardiovascular disease, sexual dysfunction and osteoporosis. Testosterone supplementation in cases of LOH will restore serum testosterone levels into the physiologic range; will restore metabolic parameters to the eugonadal state, increase muscle mass, strength, and function; maintaine or improve BMD reducing fracture risk; will improve neuropsychological function (cognition and mood); libido and sexual functioning; and enhance quality of life. The ultimate goals, however, are to maintain or regain a high quality of life, to reduce disability, to compress major illnesses into a narrow age range and to add life to years. To achieve these goals men must also adjust their lifestyle to optimize dietary habits, as well as to exercise and to abstain from smoking life-long. Monitoring these patients is a shared responsibility that cannot be taken lightly. The physician must emphasize to the patient the need for periodic evaluations and the patient must agree to comply with these requirements. The physician's evaluation should include an assessment of the clinical response and monitoring must be tailored to the indications and individual needs of the patient.

Development of a cryopreservation protocol for Leydig cells

BACKGROUND

In the present study, we describe a procedure to cryopreserve the postnatal members of the Leydig cell lineage, including progenitor (PLC), immature (ILC) and adult (ALC) Leydig cells from, respectively 21-, 35- and 90-day-old rats.

METHODS

The cells were resuspended in a culture medium supplemented with 1% bovine serum albumin (Dulbecco's Modified Eagle's Medium [DMEM]/F12) to a final concentration of 2 x 10(6)cells/ml and the effects of varying concentrations of dimethylsulfoxide (DMSO) (5, 10, 15 or 20%) were assessed after freezing at -70 degrees C and then storing in liquid nitrogen. After 12 months of frozen storage, these cells were thawed rapidly at 37 degrees C and Trypan Blue exclusion staining and attachment to culture dishes were assessed as measures of viability.

RESULTS

The trypan blue exclusion and attachment rates for Leydig cell stages were around 85% in the presence of 15% DMSO. After frozen storage, Leydig cell steroidogenic capacity in response to a range of LH doses, (0.01-100 ng/ml) was unchanged compared with freshly isolated control cells. Furthermore, the steady-state mRNA levels for Leydig cell specific transcripts were maintained.

CONCLUSIONS

This study demonstrates that purified rat Leydig cells at a range of developmental stages can be frozen and that the cryopreserved cells retain normal function.

Drug insight: testosterone preparations

Testosterone has been used for substitution therapy in testicular and hypothalamopituitary diseases for almost six decades, with injectable testosterone esters and implanted testosterone pellets being the mainstay of treatment. Growing interest in the possible use of testosterone in nonclassical situations such as male contraception, aging (late-onset hypogonadism), muscle-wasting conditions like HIV, erectile dysfunction, and female hypoactive sexual disorder has stimulated research, leading to the development of several new modes of administration of testosterone. Transdermal patches, gels, mucoadhesive sustained-release buccal tablets and long-acting testosterone esters are designed to provide testosterone levels that approximate normal physiologic levels, to improve patient acceptability, and to further increase the number of treatment options available. In this Review, we briefly describe the chemistry, mechanism of action, and metabolism of testosterone. We then discuss the pharmacokinetics, advantages, and disadvantages of various formulations and summarize the various preparations currently available.

Emerging drugs for hypogonadism

Male hypogonadism is a common endocrine problem that affects men of all ages. Recently, there has been a surge in testosterone use among middle-aged and older men who in the past may have been considered to have borderline or even normal testosterone levels. This increasing use of testosterone therapy among men has paralleled the increasing improvements in the development of treatments for male hypogonadism that have been made over the past few decades. Current therapies using transdermal formulations and long-acting injectables such as testosterone undecanoate are quickly replacing the old injectable testosterone esters. In recent years, pharmaceutical sales and prescription data have readily shown a shift in the testosterone marketplace towards greater use of slightly more expensive treatments such as transdermal therapies, which are easier to administer and yield more physiological levels of testosterone. On the horizon are several new compounds in development, such as selective androgen receptor modulators (SARMS), 7alpha-methyl-19-nortestosterone, aromatase inhibitors, clomifene, dihydrotestosterone and human chorionic gonadotropin. Compounds such as SARMs are designed to selectively target androgen receptors in specific tissues (such as bone and muscles), in the hope of dispersing some of the side effects experienced on the prostate, which are presently associated with therapy of exogenous testosterone.

Testosterone Hormone Replacement Therapy: State-of-the-Art and Emerging Technologies

In the human male, testosterone is the major circulating androgen. The clinical effects of androgen are numerous, and testosterone deficiency is associated with a number of clinical abnormalities. At present, a variety of preparations containing testosterone is available for the treatment of androgen deficiency. Ideally, those treatments have to produce and maintain physiologic serum concentrations of the hormone. This article reviews the current existing testosterone dosage forms on the market with their advantages and drawbacks and examines new and emerging technology developments concerning this therapy. In particular, the latest innovations in transdermal delivery are explored.

Comparison of the steady-state pharmacokinetics, metabolism, and variability of a transdermal testosterone patch versus a transdermal testosterone gel in hypogonadal men

AIM

To compare the pharmacokinetics (PK), metabolism, intra- and inter-subject variability of a permeation-enhanced testosterone patch versus a topical testosterone gel.

METHODS

28 hypogonadal men were treated with a testosterone patch (5 mg/day applied at 2200 h) and a 1% testosterone gel (5 g/day applied at 0800 h; nominal delivery 5 mg/day), each for 14 days, in an open-label crossover design. PK profiles of total testosterone (TT) and calculated free testosterone (cFT) were measured on day 7 and day 14 of each treatment, with patches or gel applied to the abdomen; dihydrotestosterone (DHT) and estradiol (E2) profiles were measured on day 14. The time-average (Cavg), maximum (Cmax), time of maximum (Tmax) and minimum concentrations (Cmin) were derived from each profile. The intra- and inter-subject coefficients of variation (CVintra and CVinter) of the TT and cFT parameters were computed by ANOVA.

RESULTS

Nightly applications of the patch produced a mean TT profile that mimicked the circadian pattern of healthy men. Morning applications of the gel produced a flatter mean profile; though individual subjects exhibited significant peaks at variable times. For TT, the mean and 90% confidence intervals of the patch/gel ratio of Cavg (1.030; 0.936-1.133; P > 0.05) and Cmax (1.086; 0.974-1.211; P > 0.05) met the criteria for bioequivalence. Cmin was lower for the patch. DHT levels and DHT/T ratios were 2 to 3-fold higher for the gel (P < 0.0001). E2 levels and E2/T ratios were comparable. CVintra and CVinter for Tmax approached 100% for the gel and were 23% and 42%, respectively, for the patch (P < 0.0001). Other variability parameters were generally comparable. Both products were well tolerated, and the patches adhered well.

CONCLUSIONS

These findings reflect the different mechanisms of transdermal absorption from the patch and gel and provide new considerations for selecting testosterone replacement therapies in hypogonadal men.

Aging Males’ Symptoms scale in Japanese men attending a multiphasic health screening clinic

OBJECTIVES

The Aging Males' Symptoms (AMS) scale is a health-related quality-of-life scale. The AMS scale has been used worldwide for the evaluation of andropause symptoms, but its standardized values have only been published for Germany. We sought to evaluate the prevalence of andropause symptoms in the male Japanese population using the AMS scale.

METHODS

Of a consecutive series of 2833 men who underwent multiphasic health screening at Kurashiki Central Hospital, we analyzed the results for 2211 men who responded to all questions on the AMS scale.

RESULTS

The severity of the total score and the sexual subscore of the AMS scale increased significantly with age, but no significant age relationships were observed in the psychological and somatic subscores. Approximately 50% of men in their 40s had moderate or severe symptoms in the sexual subscore. The total scores and all subscores for the Japanese population were significantly greater than those for the German population.

CONCLUSIONS

A decline in sexual function with age was demonstrated in healthy Japanese men, but the somatic and psychological subscores were not influenced by age. The present study has provided standardized values for the AMS scale for the Japanese population.

Open-Label Pilot Study of Testosterone Patch Therapy in Men With Opioid-Induced Androgen Deficiency

We conducted a 24-week open-label pilot study of testosterone (T) patch therapy in 23 men with opioid-induced androgen deficiency (OPIAD). The T dosage was 5 mg/day for the first 12 weeks and 7.5 mg/day for the second 12 weeks. Seven subjects discontinued prematurely: 4 for noncompliance, 2 for skin irritation and 1 for hepatitis C treatment. In the "completers" population (n = 16), mean (SD) free T levels (normal range 52 to 280 pg/mL) were 28.5 (18.6) pg/mL at baseline, 72.8 (29.6) pg/mL on 5 mg/day (P < .001 vs. baseline), and 120.2 (69.5) pg/mL on 7.5 mg/day (P < .001 vs. baseline and P < .01 vs. 5 mg/day). Total T, dihydrotestosterone, and estradiol showed parallel changes. Sex hormone-binding globulin levels were elevated at baseline and decreased modestly with treatment (P < .05 vs. baseline at 5 mg/day; P < .01 vs. baseline at 7.5 mg/day). Luteinizing hormone levels were in the low-normal range at baseline and suppressed markedly with treatment (P < .001 vs. baseline at both doses). Androgen deficiency symptoms (ADSQ), sexual function (Watts SFQ), mood (PGWB), depression (BDI-II), and hematocrit levels showed improvement during treatment, generally more so at the 7.5 mg/day dosage (P < .001 vs. baseline for most parameters). Pain scores (BPI-SF) decreased slightly on 7.5 mg/day (interference score: P < .05 vs. baseline and 5 mg/day); the use of opioids did not change appreciably. The testosterone patches were generally well tolerated.

PERSPECTIVE

Long-acting opioid preparations suppress the hypothalamic-pituitary-gonadal axis in men and produce a symptomatic state of opioid-induced androgen deficiency (OPIAD). Testosterone patch therapy at a dose of 7.5 mg/day normalizes hormone levels and appears to improve a number of quality of life parameters (eg, sexual function, well-being, mood) in men with OPIAD.

Anterior pituitary hormone abnormalities following traumatic brain injury

Traumatic brain injury (TBI) leads to approximately 100 hospitalizations per 100,000/year. Whereas diabetes insipidus is a well-known complication of TBI, anterior hypopituitarism as a consequence of TBI has been regarded as rare. More recent studies, however, suggest a prevalence of at least 30% of anterior pituitary dysfunction after TBI. Clinical signs of anterior hypopituitarism are often subtle and may be masked by sequalae of TBI. Therefore, post-traumatic anterior pituitary dysfunction may remain undiagnosed and, possibly, aggravate symptoms of brain injury. Moreover it may, if undiagnosed, lead to potentially fatal endocrine crises. This review updates clinical researchers, physicians, and other healthcare providers on the relationship between TBI and subsequent anterior pituitary insufficiency.

Male hypogonadism : an update on diagnosis and treatment

Male hypogonadism is one of the most common endocrinologic syndromes. The diagnosis is based on clinical signs and symptoms plus laboratory confirmation via the measurement of low morning testosterone levels on two different occasions. Serum luteinizing hormone and follicle-stimulating hormone levels distinguish between primary (hypergonadotropic) and secondary (hypogonadotropic) hypogonadism. Hypogonadism associated with aging (andropause) may present a mixed picture, with low testosterone levels and low to low-normal gonadotropin levels. Androgen replacement therapy in hypogonadal men has many potential benefits: improved sexual function, an enhanced sense of well-being, increased lean body mass, decreased body fat, and increased bone density. However, it also carries potential risks, including the possibility of stimulating the growth of an occult prostate cancer. The benefits of androgen therapy outweigh the risks in men with classic hypogonadism. However, for men with mild hypogonadism or andropause, the balance between benefits and risks is not always clear. Unfortunately, studies to date have included too small a number of patients and have been too short in duration to provide meaningful data on the long-term risks versus the benefits of androgen replacement therapy in these populations. Several products are currently marketed for the treatment of male hypogonadism. Weekly-to-biweekly injections of testosterone cypionate (cipionate) or testosterone enanthate (enantate) are widely used, as they are economical and generally well tolerated. However, once-daily transdermal therapies have become increasingly popular and now include both patch and gel systems. Intramuscular injection of testosterone undecanoate is an attractive new therapy that can be administered quarterly. To confirm an adequate replacement dosage, assessment of clinical responses and measurement of serum testosterone levels generally suffice. For selected men, serial measurement of bone mineral density during androgen therapy might be helpful to confirm end-organ effects. For men aged >50 years, we advocate measurement of hematocrit for detection of polycythemia and a digital rectal examination with a serum prostate-specific antigen level measurement for prostate cancer screening during the first few months of androgen therapy. Subsequently, a hematocrit should be obtained yearly or after changes in therapy, and annual prostate cancer screening can be offered to the patient after a discussion of its risks and benefits.

A rational approach to androgen therapy for hypogonadal men with prostate cancer

With earlier detection and improved survival from early stage prostate cancer, it is likely that the numbers of men presenting with hypogonadal symptoms following curative surgery for their cancer will increase. Although testosterone supplementation is effective in improving symptoms of hypogonadism, traditionally such therapy has been contraindicated in patients who have had prostate cancer. This paper reviews the evidence that testosterone therapy can be safely given to selected men with hypogonadism who have had prostate cancer but currently have no evidence of disease by clinical and prostate-specific antigen (PSA) criteria. Such patients should be treated cautiously and followed closely.

Testosterone replacement therapy for male hypogonadism: Part III. Pharmacologic and clinical profiles, monitoring, safety issues, and potential future agents

Male hypogonadism is associated with potentially distressing adverse effects on diverse organs and tissues. These include sexual dysfunction, particularly diminished libido, as well as mood disturbances, reduced lean body mass, and increased adipose-tissue mass. A wide range of effective and well-tolerated options exists. These include relatively noninvasive therapies, such as testosterone (T) gels and T patches; slightly more invasive treatments, such as the T buccal system; and invasive therapies, such as intramuscular T injections and subcutaneous depot implants (T pellets). Testosterone replacement therapy (TRT) can be individualized to enhance patient health and well-being. Screening and ongoing monitoring are necessary to ensure both the efficacy and safety of TRT, particularly prostate safety. Investigational agents, including selective androgen receptor modulators, may offer new pharmacodynamic and/or pharmacokinetic properties that enhance outcomes of TRT.

Testosterone therapy in men with moderate severity heart failure: a double-blind randomized placebo controlled trial

AIMS

Chronic heart failure is associated with maladaptive and prolonged neurohormonal and pro-inflammatory cytokine activation causing a metabolic shift favouring catabolism, vasodilator incapacity, and loss of skeletal muscle bulk and function. In men, androgens are important determinants of anabolic function and physical strength and also possess anti-inflammatory and vasodilatory properties.

METHODS AND RESULTS

We conducted a randomized, double-blind, placebo-controlled parallel trial of testosterone replacement therapy (5 mg Androderm) at physiological doses in 76 men (mean+/-SD, age 64+/-9.9) with heart failure (ejection fraction 32.5+/-11%) over a maximum follow-up period of 12 months. The primary endpoint was functional capacity as assessed by the incremental shuttle walk test (ISWT). At baseline, 18 (24%) had serum testosterone below the normal range and bioavailable testosterone correlated with distance walked on the initial ISWT (r=0.3, P=0.01). Exercise capacity significantly improved with testosterone therapy compared with placebo over the full study period (mean change +25+/-15 m) corresponding to a 15+/-11% improvement from baseline (P=0.006 ANOVA). Symptoms improved by at least one functional class on testosterone in 13 (35%) vs. 3 (8%) on placebo (P=0.01). No significant changes were found in handgrip strength, skeletal muscle bulk by cross-sectional computed tomography, or in tumour necrosis factor levels. Testosterone therapy was safe with no excess of adverse events although the patch preparation was not well tolerated by the study patients.

CONCLUSION

Testosterone replacement therapy improves functional capacity and symptoms in men with moderately severe heart failure.

Testim® 1% testosterone gel for the treatment of male hypogonadism

OBJECTIVE

The aim of this work was to review the pharmacokinetic and clinical profile of Testim (Auxilium Pharmaceuticals, Norristown, Pennsylvania) 1% gel formulation of testosterone for the treatment of male hypogonadism.

METHODS

An English-language search of the medical literature was conducted using PubMed (1998-December 2004) and EMBASE (1998-December 2004). Search terms included ag(e)ing male, male hypogonadism, late-onset hypogonadism, testosterone, testosterone deficiency, testosterone therapy, testosterone replacement therapy, androgen therapy, testosterone gel, and Testim. Bibliographies of retrieved articles were also reviewed.

RESULTS

Five published clinical studies were reviewed. Testim 50 mg showed clear pharmacokinetic differences from AndroGel (known as Testogel in Europe; Unimed Pharmaceuticals, Inc., and Solvay Pharmaceuticals, Inc., Marietta, Georgia) 1% testosterone gel 50 mg, with increases of 30% (90% CI, 8%-57%) and 47% (90% CI, 20%-79%) versus AndroGel, respectively, in AUC(0-24h) for total serum testosterone and free testosterone. In a 30-day study of 638 men with hypogonadism, sexual desire scores and sexual motivation scores increased after Testim treatment at weeks 1, 2, 3, and 4 (each, P < 0.001). During 12 months of treatment with Testim 50 or 100 mg in 371 men with hypogonadism, total serum testosterone levels were raised to and maintained within the normal adult range, lean body mass increased by 2.2 kg (P < 0.001), fat mass fell by 2.1% (P < 0.001), and bone mineral density increased by 2.58% (P < 0.001). Mean scores for sexual desire, performance, motivation, and spontaneous erections were all significantly higher (all, P < 0.001) than at baseline for all time points during 12-month studies of Testim. In 2 studies comparing Testim with different testosterone patches, treatment with the gel resulted in 10-fold fewer application-site reactions than either patch.

CONCLUSIONS

In men with hypogonadism, Testim gel raised and maintained serum testosterone levels to within the normal adult range, alleviated signs and symptoms associated with hypogonadism, and was well tolerated.

The therapeutic potential of testosterone patches

In the last decade, transdermal delivery of testosterone (T) has been shown to be a safe and effective means of treating male hypogonadism. Transdermal T patches can provide for physiologic androgen replacement in over 90% of men with hypogonadism. In addition, T patches have been shown to be equivalent to im. T esters in restoring normal male libido,sexual function and bone mineral density without harmful side-effects.Furthermore, in sharp contrast to periodic im. injections of T, transdermal T patches, when used daily, restore the normal circadian rhythm of T levels. The physiological and clinical importance of these circadian patterns,however, is presently unknown. The first transdermal patch to be marketed is applied to shaved scrotal skin. Newer patches can be applied to non-scrotal skin; however, these patches are associated with a significant rate of skin reactions that may require discontinuation. The main drawback to transdermal T delivery is cost, ten to twenty times the monthly cost of im. T, the method currently used to treat most hypogonadal men.Nevertheless, transdermal T patches constitute a major advance in the therapy of male hypogonadism as they allow for safe, non-invasive administration of T.

Testosterone does not adversely affect fibrinogen or tissue plasminogen activator (tPA) and plasminogen activator inhibitor-1 (PAI-1) levels in 46 men with chronic stable angina

OBJECTIVE

In women, sex hormones cause increased morbidity and mortality in patients with coronary heart disease (CHD) and adversely affect the coagulation profile. We have studied the effect of physiological testosterone replacement therapy in men on coagulation factor expression, to determine if there is an increased risk of thrombosis.

METHODS

Double-blind, randomized, placebo-controlled trial of testosterone in 46 men with chronic stable angina. Measurements of free, total and bioavailable testosterone, luteinising hormone (LH) and follicle-stimulating hormone (FSH), estradiol, plasminogen activator inhibitor-1 (PAI-1), fibrinogen, tissue plasminogen activator (tPA) and full blood count were made at 0, 6 and 14 weeks.

RESULTS

Bioavailable testosterone levels were: 2.58 +/- 0.58 nmol/l at baseline, compared with 3.35 +/- 0.31 nmol/l at week 14 (P < 0.001) after treatment compared with 2.6 +/- 0.18 nmol/l and 2.44 +/- 0.18 nmol/l in the placebo group (P was not significant). There was no change in fibrinogen (3.03 +/- 0.18 g/l at baseline and 3.02 +/- 0.18 g/l at week 14, P = 0.24), tPA activity (26.77 +/- 4.9 Iu/ml and 25.67 +/- 4.4 Iu/ml, P = 0.88) or PAI-1 activity (0.49 +/- 0.85 Iu/ml and 0.36 +/- 0.06 Iu/ml, P = 0.16) with active treatment and no differences between the groups (at week 14, P value 0.98, 0.59 and 0.8 for fibrinogen, PAI-1 and tPA respectively). Haemoglobin concentration did not change over time, in the testosterone group (1.44 +/- 0.02 g/l and 1.45 +/- 0.02 g/l, P = 0.22).

CONCLUSION

Physiological testosterone replacement does not adversely affect blood coagulation status.

Sexual functioning and satisfaction in nonresponders to testosterone gel: Potential effectiveness of retreatment in hypogonadal males

There is a slow but continuous decline in testosterone (T) levels with age, with a substantial percentage of males exhibiting T levels in the hypogonadal range. This age-dependent decline in circulating androgens is associated, in large part, with reduced sexual functioning and libido. The effectiveness of TestimR 1% (Auxilium Pharmaceuticals, Inc., Norristown, Pennsylvania) topical T gel was evaluated in older hypogonadal males who failed to experience satisfactory symptom relief after treatment with AndroGelR 1% (Solvay Pharmaceuticals, Inc., Marietta, Georgia). In this open-label study, consecutive subjects were assigned randomly to experimental treatment with Testim 1% (5 g) or to maintenance therapy (control group) with AndroGel 1% (5 g). Seventy-six experimental subjects and 75 control subjects were followed for 4 weeks to evaluate improvements in sexual functioning and satisfaction. Changes from baseline in the 5 domains of the Brief Male Sexual Function Inventory were compared between groups. The mean percentage improvement favored the experimental treatment in sexual drive (23% vs 16%, P < 0.3), erectile function (32% vs 8%, P < 0.03), ejaculatory function (11% vs 9%, P < 0.4), problem assessment (47% vs 12%, P < 0.01), and sexual satisfaction (62% vs 23%, P < 0.02). A greater percentage of subjects also reported satisfaction with the experimental treatment (55% vs 33%, P < 0.02), and these subjects were less likely to require upward dose titration at the final follow-up visit (53% vs 72%, P < 0.03). Consideration of Testim 1% gel in patients who have an inadequate response to prior T therapy is encouraged, although it is difficult to estimate the contribution of nonspecific study effects (eg, placebo) in this trial.

ANDROGEN REPLACEMENT AFTER CURATIVE RADICAL PROSTATECTOMY FOR PROSTATE CANCER IN HYPOGONADAL MEN

PURPOSE

We documented the experience of 2 urology practices with the use of testosterone supplementation to treat hypogonadal men who had undergone curative radical prostatectomy for localized prostate cancer. We also reviewed the literature for reports of the use of testosterone in men surgically cured of prostate cancer.

MATERIALS AND METHODS

A retrospective review of clinical records of 2 busy private urology practices was used to compile brief case histories of hypogonadal men treated with testosterone who had undergone curative radical prostatectomy for localized prostate cancer. Using MEDLINE and BIOSIS Previews (Biological Abstracts, Inc., Philadelphia, Pennsylvania), the literature was searched for articles describing the use of testosterone in men surgically cured of organ confined prostate cancer.

RESULTS

The case records of 7 hypogonadal men who had undergone curative radical prostatectomy were identified. All men had clinical symptoms of hypogonadism and low serum testosterone levels. Each man was treated with an androgen preparation. After variable followup periods no biochemical or clinical evidence of cancer recurrence was found in any of the group. No reports in the literature were found of a similar therapeutic approach for such patients.

CONCLUSIONS

Based on the clinical experience with this small group of men, and indirect evidence of the safety of this approach from epidemiological and clinical data, further cautious use of testosterone in a carefully selected population seems warranted.

11: Androgen deficiency and replacement therapy in men

Androgen deficiency is a clinical diagnosis confirmed by hormone assays. Among younger men, androgen deficiency is usually due to underlying hypothalamopituitary or testicular disorders. Androgen replacement therapy should be started after proof of androgen deficiency and should continue lifelong with monitoring. Men presenting with erectile dysfunction should be evaluated for androgen deficiency, but it is an uncommon cause; if overt androgen deficiency is confirmed, an underlying disorder needs further specialist investigation. In the absence of characteristic underlying testicular or pituitary disorders, new diagnosis of androgen deficiency in older men is difficult because of the non-specific symptoms and the decline in blood testosterone levels seen in healthy ageing and chronic medical disorders. There remains no convincing evidence that androgen therapy is either effective treatment or safe for older men unless they have frank androgen deficiency.

Male hypogonadism in the primary care clinic

Hypogonadism is common in clinical practice but is frequently unrecognized and underdiagnosed. The common causes of male hypogonadism vary with the age of presentation. The overall prevalence of male hypogonadism based upon low serum total testosterone levels is high and increases with age. There are many pitfalls in making the diagnosis of male hypogonadism. First, male hypogonadism is sometimes difficult to recognize because the signs and symptoms are often nonspecific and overlap with other common syndromes. Second, the biochemical diagnosis of male hypogonadism is not straightforward because it might not be clear which testosterone assay to select from the many that are available. Finally, even after the diagnosis of male hypogonadism is made, the patient and clinician must weigh the potential benefits and risks of androgen replacement therapy. However, new diagnostic tools and therapies are making decisions easier.

Transdermal testosterone gel: pharmacokinetics, efficacy of dosing and application site in hypogonadal men

OBJECTIVE

To determine the regimen that would most effectively maintain serum testosterone concentrations in treated hypogonadal men within the normal reference range of 3-11.4 microg/L.

PATIENTS AND METHODS

Eighteen men aged 24-69 years with either primary or secondary hypogonadism participated in and 16 completed a randomized, six-treatment regimen, three-period (phase), three-way matrix-type crossover study. A 1% and 2% testosterone gel (CP601, Cellegy Pharmaceuticals, Inc., San Francisco, USA) was administered either once or twice daily transdermally at different body sites to determine optimal dosing, application sites, and its pharmacokinetics and tolerability in hypogonadal men. Treatments A-F included 1 g of 1% and 2% gel that was equivalent to 10 or 20 mg of testosterone, applied once or twice daily to the skin of either the thigh or the upper arm. Six men also participated in a study of 3 g of 2% gel that was equivalent to 60 mg of testosterone applied once daily, half on each thigh. Pharmacokinetic variables were calculated for testosterone for each man in each treatment period and the results analysed by anova.

RESULTS

In general the higher dose regimens produced higher serum concentrations of testosterone; the 3 g/2% dose was most successful in maintaining serum testosterone within the normal reference range. The average testosterone concentration (C(avg)) was 6.52 microg/L and all men had a C(avg) of > 3.0 microg/L. The prediction of all men achieving a C(avg) of > 3.0 microg/L was 96%. The mean minimum concentration (C(min)) was 3.83 microg/L and half the patients had a C(min) of > 3.0 microg/L. Most men had serum testosterone levels within the normal reference range throughout the 24 h, and the treatment was well tolerated.

CONCLUSIONS

The 3 g/2% dose applied to the skin daily resulted in serum testosterone in the normal reference range in most hypogonadal men. Dose adjustments to either a lower or higher dose should shift serum testosterone concentration to the desired range in those who do not achieve this range with this dose.

The endocrine pharmacology of testosterone therapy in men

The review starts off by outlining the history of the discovery of the male sex hormone testosterone and the historical background to the various, often dubious, approaches to the treatment of age-related endocrine disorders in older men. A discussion of congenital androgen deficiency in young men is followed by methods of diagnosing hypogonadism in older men. Among therapeutic options, the alternatives to direct testosterone replacement are discussed, although none of them have proved to be particularly successful in clinical practice. For testosterone replacement itself, various routes of administration and pharmaceutical formulations are now available, facilitating good monitoring and individualized therapy.