Déficit androgénique lié à l’âge. Que faut-il attendre de l’androgénothérapie?

With the exception of disease or drug-induced changes in Leydig cell function, aging is accompanied by specific changes of androgen status in healthy men. The level of testosterone production decreases in contrast with the rise in plasma protein testosterone binding capacity. Free testosterone, considered to be the biologically active fraction, decreases, leading to tissue androgen deficiency. The resulting clinical picture mimics hypogonadism, including physical and psychological asthenia, decreased libido and sexual behaviour, increased fat mass and decreased lean mass, gynaecomastia, osteoporosis and pro-atherogenic metabolic changes. The cut-off value for plasma testosterone below which androgen deficiency can be considered to be responsible for clinical signs is a key point which determines the therapeutic approach. In the absence of clearly validated data in healthy aging males, this cut-off value has been consensually defined as the mean plasma testosterone levels of men between 30 and 50 years of age minus two standard deviations, corresponding to the zone of hypogonadism in adult males. The association of clinical signs compatible with hypogonadism and reduced total (or preferably bioavailable) plasma testosterone level justifies initiation of hormone replacement therapy after excluding any contraindications (especially prostatic). The aim of this treatment is to reverse the consequences of age-related hypogonadism. Some benefits of this treatment have been clearly demonstrated, such as a decrease of fat mass, and an increase of lean mass and muscle strength. Similarly, bone mineral density increases, particularly in men with the lowest pretreatment plasma testosterone levels. It must be stressed that these changes are observed in truly hypogonadal aging men, but not in aging men with normal plasma testosterone levels. Testosterone replacement therapy can promote the development of gynaecomastia, while dihydrotestosterone tends to reduce gynaecomastia. Finally, androgen replacement therapy appears to improve a hypogonadism-related decrease in libido or sexual behaviour, provided other associated non-endocrine factors have been previously treated. Androgen replacement therapy improves well-being, and physical and psychological asthenia in hypogonadal men. However, this treatment has not been demonstrated to be effective in healthy aging men. Although androgen replacement therapy does not have a negative impact on lipid parameters, its possible cardiovascular protective effects have not yet been demonstrated. In conclusion, androgen replacement therapy, respecting the contraindications, is beneficial in patients of all ages with clearly demonstrated hypogonadism, but has no efficacy on symptoms in other cases.     

Prostate cancer risk in testosterone-treated men

Men with classical androgen deficiency have reduced prostate volume and blood prostate-specific antigen (PSA) levels compared with their age peers. As it is plausible that androgen deficiency partially protects against prostate disease, and that restoring androgen exposure increases risk to that of eugonadal men of the same age, men using ART should have age-appropriate surveillance for prostate disease. This should comprise rectal examination and blood PSA measurement at regular intervals (determined by age and family history) according to the recommendations, permanently revisited, published by ISSAM, EAU, Endocrine Society….

Testosterone replacement therapy is now being prescribed more often for aging men, the same population in which prostate cancer incidence increases; it has been suggested that administration in men with unrecognised prostate cancer might promote the development of clinically significant disease. In hypogonadal men who were candidates for testosterone therapy, a 14% incidence of occult cancer was found. A percentage (15.2%) of prostate cancer has been found in the placebo group (with normal DRE and PSA) in the prostate cancer prevention study investigating the chemoprevention potential of finasteride.

The hypothesis that high levels of circulating androgens is a risk factor for prostate cancer is supported by the dramatic regression, after castration, of tumour symptoms in men with advanced prostate cancer. However these effects, seen at a very late stage of cancer development, may not be relevant to reflect the effects of variations within a physiological range at an earlier stage.

Data from all published prospective studies on circulating level of total and free testosterone do not support the hypothesis that high levels of circulating androgens are associated with an increased risk of prostate cancer. A study on a large prospective cohort of 10,049 men, contributes to the gathering evidence that the long standing “androgen hypothesis” of increasing risk with increasing androgen levels can be rejected, suggesting instead that high levels within the reference range of androgens, estrogens and adrenal androgens decrease aggressive prostate cancer risk. Indeed, high-grade prostate cancer has been associated with low plasma level of testosterone. Furthermore, pre-treatment total testosterone was an independent predictor of extraprostatic disease in patients with localized prostate cancer; as testosterone decreases, patients have an increased likelihood of non-organ confined disease and low serum testosterone levels are associated with positive surgical margins in radical retropubic prostatectomy.

A clinical implication of these results concerns androgen supplementation which has become easier to administer with the advent of transdermal preparations (patch or gel) that achieve physiological testosterone serum levels without supra physiological escape levels. During the clinical development of a new testosterone patch in more than 200 primary or secondary hypogonadal patients, no prostate cancer was diagnosed.     

Androgénothérapie: Quels sont les risques?

Androgens play an important biological role at all phases of a man’s life. The objective of treatment of androgen deficiency is to maintain physiological testosterone levels. Misuse and abuse of androgen as anabolic steroids are frequent in sportsmen and body-builders or for erectile dysfunction. The main concerns for the potential adverse effects of testosterone treatment are the prostate and the cardiovascular system (lipid metabolism). Liver function must also be monitored. There is no evidence, at the present time, that testosterone replacement therapy in hypogonadal men increases the risk of prostate cancer. Only sporadic cases have been reported. Because of the risk of stimulating an existing prostate cancer, each patient must be monitored every six months (PSA and DRE).     

Androgen replacement therapy in the aging male

Beginning around age 40 years, men experience a decrease in testosterone level-referred to as "andropause"-and the pathophysiologic changes that accompany this decrease. Androgen replacement therapy, typically used for the treatment of senile hypogonadism, is evolving as a potential treatment of various other conditions related to testosterone loss, such as osteoporosis, sarcopenia, and even psychological symptoms. As with any treatment modality, certain patient factors are more predictive of success with minimal adverse effects, and consideration must be given to concomitant conditions. This article will provide a review of recent studies examining the effects of androgen supplementation and evaluate the purported benefits and potential risks of this therapy. Further research is anticipated to elucidate the most appropriate candidates, as well as other potential indications, for this treatment.     

Does Testosterone Therapy Increase the Risk of Prostate Cancer?

ObjectiveTo review factors affecting use of testosterone therapy for hypogonadism including the persistent controversial link between testosterone therapy and prostate cancer.MethodsWe reviewed studies investigating the relationship between testosterone therapy and prostate cancer progression and summarized strategies for hypogonadism management and prostate monitoring.ResultsTrials of up to 36 months in length and longitudinal studies consistently fail to demonstrate an increased prostate cancer risk associated with increased testosterone levels. No evidence of an associated relationship between exogenous testosterone therapy and prostate cancer has emerged from clinical trials or adverse event reports. It does not appear that exogenous testosterone accumulates in the prostate or provokes major biologic change in the prostate gland. In addition, preliminary evidence indicates that low endogenous testosterone may confer an increased risk of prostate cancer.ConclusionsMounting evidence demonstrates that there is a lack of association between testosterone therapy and prostate cancer progression. Testosterone therapy may be prescribed for men for whom it was once not considered. Careful monitoring of patients with hypogonadism who are receiving testosterone therapy is imperative. Well-designed, large-scale prospective clinical trials are necessary to adequately address prostate safety in hypogonadal men receiving testosterone therapy. (Endocr Pract. 2008;14:904-911)     

Fundamental aspects of hypogonadism in the aging male

With aging in men, serum testosterone levels decline progressively and the prevalence of hypogonadism increases; these changes are associated with alterations in androgen-regulated physiological functions. In young hypogonadal men, similar alterations improve with testosterone replacement. In older men, short-term testosterone treatment trials suggest benefits (eg, on body composition and bone mineral density), without significant adverse effects. Therefore, androgen deficiency may contribute to physiological decline with aging, and testosterone therapy is reasonable for older men with clinical manifestations of androgen deficiency and low testosterone levels. However, the long-term benefits and potential risks (eg, for prostate disease) of testosterone treatment in older men are unknown.     

Androgen deficiency in the aging male: benefits and risks of androgen supplementation

There is now convincing evidence that in a subset of aging men, increasing with age, plasma testosterone levels fall below a critical level resulting in hypogonadism. This state of testosterone deficiency has an impact on bone, muscle and brain function and is maybe a factor in the accumulation of visceral fat which again has a significant impact on the cardiovascular risk profile. From the above it follows that androgen replacement to selected men with proven androgen deficiency will have beneficial effects. There is, however a concern that androgen administration to aging men may be harmful in view of effects on prostate disease. Benign prostate hyperplasia (BPH) and prostate cancer are typically diseases of the aging male, steeply increasing with age. But epidemiological studies provide no clues that the levels of circulating androgen are correlated with or predict prostate disease. Similarly, androgen replacement studies in men do not suggest that these men suffer in a higher degree from prostate disease than control subjects. It seems a defensible practice to treat aging men with androgens if and when they are testosterone-deficient, but long-term studies including sufficient numbers of men are needed.     

Optimizing Diagnostic Accuracy and Treatment Decisions in Men With Testosterone Deficiency

ObjectiveThis narrative review offers a guideline-based approach for optimizing diagnostic evaluation and treatment decision making in men being evaluated for testosterone deficiency.MethodsA narrative review.ResultsTestosterone deficiency is a clinical syndrome that results from the inability of the testes to produce normal amounts of testosterone and is characterized by a constellation of symptoms and signs associated with consistently low testosterone concentrations. The diagnosis of testosterone deficiency is made by the ascertainment of symptoms and signs; the measurement of total and, if indicated, free testosterone levels in early-morning fasting samples on ≥2 days; the measurement of luteinizing hormone and follicular-stimulating hormone levels to distinguish primary from secondary hypogonadism; and an additional evaluation to ascertain the cause of testosterone deficiency. Nonspecificity of symptoms and signs, variations in testosterone levels over time, inaccuracy in the measurement of total and free testosterone levels, variations in binding protein concentrations, and suboptimal reference ranges contribute to diagnostic inaccuracy. Testosterone treatment is indicated for men with symptomatic testosterone deficiency. Testosterone treatment should be avoided in men with prostate or breast cancer, erythrocytosis, thrombophilia, increased risk of prostate cancer or severe lower urinary tract symptoms without prior urologic evaluation, a recent major adverse cardiovascular event, uncontrolled heart failure, or severe untreated sleep apnea. Testosterone replacement therapy should be accompanied by a standardized monitoring plan.ConclusionA shared decision of the patient and physician to treat should be guided by the consideration of the burden of symptoms, potential benefits and risks, patient’s values, and the cost and burden of long-term treatment and monitoring.     

Traitement androgénique substitutif et cancer prostatique

Epidemiological studies show that the risk of prostate cancer was not related to testosterone blood levels. Androgens do not seem to be able to cause prostatic cancer in men. However, administration of exogenous androgens can unmask a prostatic cancer that was, until then, hidden by hypogonadism. Screening of a latent prostatic cancer before the induction of an androgenic treatment must follow the usual recommendations based on digital rectal examination and PSA level determination. A special attention is to be paid when beginning an androgen replacement therapy with a control at six months; thereafter a follow up including digital rectal examination and PSA must be performed every year.     

Current state of practice regarding testosterone supplementation therapy in men with prostate cancer

Hypogonadal men are characterized by low serum testosterone and symptoms of low energy, decreased libido, and muscle mass as well as impaired concentration and sexual functioning. Men with prostate cancer (PCa) currently on active surveillance or post-therapy, have traditionally been excluded from management paradigms given the decade-old concern that testosterone caused PCa growth. However, there appears to be little or no relationship between serum testosterone concentration and PCa. Androgen action in the prostate has long been known to be affected by the kinetics of receptor saturation and, as such, testosterone beyond a certain baseline is unable to stimulate prostatic growth due to complete intra-prostatic androgen receptor binding. Given this physiologic concept, many clinical investigators have begun to promote testosterone supplementation therapy (TST) as safe in men with PCa. This review examines the basics of testosterone physiology and summarizes the most recent findings on the use of TST in men with PCa on active surveillance and following treatment with external beam radiotherapy, brachytherapy and radical prostatectomy.     

Effective Testosterone Suppression for Prostate Cancer: Is There a Best Castration Therapy?

Achieving and maintaining effective suppression of serum testosterone levels in men treated with androgen ablation is one of the essential strategies in the management of prostate cancer. Historically, a serum testosterone below 50 ng/dL was considered to be the castrate level. Current data suggest that the new target for either surgical or chemical castration is a serum testosterone level of lower than 20 ng/dL in an attempt to maximize therapeutic outcomes. Testosterone breakthrough and the acute-on-chronic effects of administration of a luteinizing hormone-releasing hormone analogue may cause testosterone levels to periodically rise, sometimes to noncastrate levels. The goal of androgen ablation is to identify those agents that will most consistently achieve and maintain the lowest testosterone levels possible.Key words: Prostate cancer, Androgen ablation, LHRH analogues, LHRH antagonists, TestosteroneThe cornerstone of understanding the basic biology of prostate cancer relies upon the important discovery that prostate cancer is a hormonally responsive tumor. The current use of androgen ablation therapy in prostate cancer includes treatment based on serum prostate-specific antigen (PSA) only or local recurrence; neoadjuvant or adjuvant treatment of high-risk disease, usually in combination with radiation therapy; and treatment of patients with metastatic disease regardless of symptoms. The American Society of Clinical Oncology (ASCO) 2007 guidelines and National Comprehensive Cancer Network (NCCN) 2009 guidelines recommend either luteinizing hormone-releasing hormone (LHRH) agonists or bilateral orchiectomy as first-line therapy for men with advanced prostate cancer.^1,2Medical or chemical castration is almost exclusively performed by the use of injectable LHRH analogues, with a minor role for estrogen and limited experience with LHRH antagonists. Surgical castration through bilateral orchiectomy is infrequently used today.Intermittent hormonal therapy (IHT) is being investigated as an alternative to continuous hormonal therapy with a potential for reduced morbidity and a delay of the progression to hormone-refractory disease.³ Although intermittent therapy may rely upon restoring a normal testosterone level, it is believed that the testosterone level should be as low as possible when the patient is on treatment, thus generating the lowest serum PSA level possible and likely improving outcome.⁴ Although the data on IHT are promising, trials reported thus far are relatively small and somewhat underpowered, and it is likely that its use will increase in the future as trials mature.There is growing recognition that many men may not achieve acceptable levels of testosterone using androgen ablation. This has led to a renewed interest in the significance of the testosterone level in the modern era of prostate cancer management. Can we define the best castration therapy for prostate cancer? Is this the therapy that provides the lowest and most consistent levels of testosterone suppression? To quote Dr. Claude Schulman in a recent editorial: “less is more.”⁵     

Invasive Breast Cancer After Initiation of Testosterone Replacement Therapy in A Man—A Warning To Endocrinologists

ObjectiveTo alert fellow endocrinologists of a rare side effect of testosterone therapy, for which men with hypogonadism must receive appropriate counseling and monitoring.MethodsWe present clinical features, laboratory data, and histopathologic findings in a man with hypogonadism who received testosterone replacement therapy.ResultsA 61-year-old man was referred to an endocrinologist after presenting to his general practitioner with erectile dysfunction and low libido. He had no history of hypothalamic, pituitary, or testicular disorders. There were no other illnesses or medications to account for low testosterone levels. Physical examination was unremarkable. There was no family history of malignant disease. Biochemical investigations confirmed the presence of primary hypogonadism, for which no cause (including Klinefelter syndrome) was identified. Testosterone therapy was initiated to improve sexual function and preserve bone density. Five weeks later, the patient returned to his general practitioner, complaining of a gradually enlarging lump in his right breast. When biopsy showed breast cancer, testosterone therapy was discontinued. Right mastectomy and axillary node clearance were performed. Further histologic examination revealed estrogen receptor-positive, invasive carcinoma, without nodal involvement. The patient remains on tamoxifen therapy and is undergoing follow-up in the breast clinic. After 6 months of treatment, estradiol levels were undetectable, and testosterone levels remained low.ConclusionAlthough breast cancer has been described in men with hypogonadism receiving long-term testosterone replacement therapy, to our knowledge this is the first report of breast cancer becoming clinically manifest after a short duration (5 weeks) of testosterone treatment. This case should remind clinicians that men receiving testosterone therapy should be warned of the risk of not only prostate cancer but also breast cancer. Patient self-monitoring and breast examinations by the attending physician are recommended. (Endocr Pract. 2008;14: 201-203)     

Associations of Sex Hormone Concentrations with Health and Life Satisfaction in Elderly Men

ObjectiveTo analyze associations between sex hormone concentrations and self-rated health and life satisfaction, neuropsychiatrie symptoms, or diagnosed depression or dementia in elderly men.MethodsThe study subjects were men from the community-based Lieto Study (N = 517). Subjects were excluded from the study if they were taking exogenous sex hormones or medication for prostate cancer or for benign prostatic hyperplasia or if data for calculating body mass index (BMI) were missing. Thus, 466 men (64 to 97 years old; mean age, 72 years; mean BMI, 26.9 kg/m²) remained for further analysis.ResultsAfter adjustment for age, higher levels of testosterone and free testosterone were associated with better self-rated health. After adjustment for age and BMI, no statistically significant associations were found between sex hormone levels and self-rated health or life satisfaction or most neuropsychiatric symptoms in elderly men. Diagnosed depression was associated with a lower serum testosterone concentration. Higher levels of luteinizing hormone and follicle-stimulating hormone were associated with diagnosed dementia.ConclusionIn this population-based study with high attendance rate, low serum testosterone concentration was associated with diagnosed depression. Subclinical hypogonadism may be associated with diagnosed dementia. Single questions on neuropsychiatric symptoms commonly associated with androgen deficiency seemed to have weak or no correlation with testosterone or free testosterone levels among this group of elderly men. (Endocr Pract. 2007;13:743-749)     

Réflexion multidisciplinaire sur la prise en charge du Déficit androgénique lié à l’âge

The diagnosis of the androgen deficiency of the aging male (ADAM) is suspected in the presence of relatively unspecific clinical symptoms. The biological evidence of androgen deficiency should be given by using an assay taking into account the level of the sex hormone binding protein (SHBG), such as the bioavailable testosterone assay or, at least, the free testosterone index or the calculated free testosterone which both require measuring total testosterone and SHBG levels. Although the threshold value for defining ADAM has not been fully investigated, the lower limit of normal values in healthy young men which is commonly used for including subjects in therapeutic trials, seems appropriate. According to the currently available data, testosterone replacement therapy in hypogonadal aging men seems to be beneficial to quality of life, sexuality, metabolic status, body composition and osteoporosis. The initiation of androgen replacement therapy requires a careful screening for prostate cancer. Prostate and hematocrit must be monitored during the replacement therapy which is intended for maintaining testosterone levels in the physiological range. Associated disease should be accounted for as a possible factor worsening ADAM and could be relevant of a specific therapy.     

Risques prostatiques de la testostérone : nouveau retour du balancier?

Since the 1940??s, testosterone (T) is deemed dangerous to the prostate, though without solid evidence. Longitudinal studies do not show association between T levels and prostate cancer (PCa) incidence. To the contrary, aggressive PCa cases are associated with low T levels. Randomized placebo controlled trials of T therapy do not show any increase in PCa incidence in the T groups. These reassuring data have led some doctors to prescribe T replacement therapy to men with prostatic intraepithelial neoplasia, or previously treated for a low grade PCa, or under active surveillance for such untreated cancer without showing a high risk of progression or recurrence of cancer with this treatment. There is however no doubt that normal prostate and PCa, at least in its advanced forms, are made with androgen-dependent tissues. These apparent contradictions might be explained, besides the possibility of a very low diffusion of circulating T in the prostate, by the hypothesis of a saturation of the prostate androgen receptors from very low levels of circulating T, close to castration levels, explaining that an increase in T beyond this level cannot stimulate the prostate tissue. Some recent reports of PCa progression under T therapy, sometimes persisting despite T withdrawal, show that the reassuring results of the previous studies cannot be generalized. Objective data also suggest that the saturation level of the prostate androgen receptor is actually close to the lower limit of the normal T range. We must remain cautious about expanding the indication of T therapy in men with a history of PCa. Only large-scale, randomized, double-blind placebo controlled trials, will provide reliable information on the prostatic risks of such a treatment.     

Case scenarios in androgen deficiency

Deciding whether to choose androgen replacement for a particular patient is one of the many tasks facing the urologist. Factors including androgen levels, medical history, symptom profile, current medications, and prostate cancer risk all need to be considered when making this decision. However, the role each of these factors plays in arguing for or against androgen replacement remains controversial and more research is needed in many of these areas before the outstanding issues can be resolved. This article presents three cases involving patients who may require androgen supplementation. The cases describe (1) partial androgen deficiency syndrome, (2) testosterone deficiency in an anorchic man after bilateral orchiectomy for seminoma, and (3) a patient with sildenafil-refractory erectile dysfunction following treatment of localized prostate cancer with radiation therapy and androgen ablation. These cases illustrate some of the dilemmas and controversies surrounding androgen replacement that face the practicing urologist.     

Androgens as therapy for androgen receptor-positive castration-resistant prostate cancer

Prostate cancer is the most frequently diagnosed non-cutaneous tumor of men in Western countries. While surgery is often successful for organ-confined prostate cancer, androgen ablation therapy is the primary treatment for metastatic prostate cancer. However, this therapy is associated with several undesired side-effects, including increased risk of cardiovascular diseases. Shortening the period of androgen ablation therapy may benefit prostate cancer patients. Intermittent Androgen Deprivation therapy improves quality of life, reduces toxicity and medical costs, and delays disease progression in some patients. Cell culture and xenograft studies using androgen receptor (AR)-positive castration-resistant human prostate cancers cells (LNCaP, ARCaP, and PC-3 cells over-expressing AR) suggest that androgens may suppress the growth of AR-rich prostate cancer cells. Androgens cause growth inhibition and G1 cell cycle arrest in these cells by regulating c-Myc, Skp2, and p27^Kip via AR. Higher dosages of testosterone cause greater growth inhibition of relapsed tumors. Manipulating androgen/AR signaling may therefore be a potential therapy for AR-positive advanced prostate cancer.     

Diagnostic et traitement du déficit en androgènes des patients infectés par le virus de l’immunodéficience humaine

Androgen deficiency is frequent among men infected by the human immune deficiency virus (HIV), with an estimated prevalence of between 35% and 50%. Primary testicular damage has been described, either due to the virus itself, opportunistic agents such as CMV,Toxoplasma gondii orMycobacterium avium intracellulare, or less frequently neoplastic invasion by lymphoma or in a context of Kaposi’s sarcoma. However, secondary hypogonadism remains a more frequent cause. Hypogonadotropic hypogonadism can be secondary to opportunistic infections, malnutrition, and sometimes even certain therapeutic agents. Since the introduction of highly active antiretroviral therapies, the prevalence of hypogonadism has substantially decreased. However, it remains a significant clinical problem, particularly among patients suffering from wasting, as androgen deficiency may aggravate the loss of lean body mass observed in the wasting syndrome of HIV patients. Screening for androgen deficiency is therefore indicated in HIV patients suffering from wasting, even in the absence of specific symptoms. Androgen replacement therapy is justified in symptomatic (loss of libido, impotence) and asymptomatic patients with documented hypogonadism. We recommend replacement therapy with testosterone by subcutaneous or intramuscular injection. In the absence of specific symptoms, it should be remembered that testosterone replacement therapy of HIV-infected hypogonadic patients is associated with improvements in body composition and muscle strength, bone densitometry, quality of life and mood. Similar improvements have also been demonstrated in hypogonadic patients with wasting syndrome. Synthetic testosterone analogues such as oxandrolone or nandrolone do not seem to be more powerful than testosterone at replacement doses, and may be associated with more side effects, particularly severe hepatic dysfunction. In contrast, there is no proven benefit of androgen treatment of eugonadic HIV-infected patients, and the treatment of such patients with androgens, even in the presence of wasting, cannot be recommended.     

Déficit Androgénique Lié à l’Age

In contrast with the abrupt cessation of ovarian function at menopause in women, alteration of testicular functions in aging males is partial and progressive. Several cross-sectional studies have demonstrated an age-related decrease of testosterone levels in men. This decrease has also been observed when only men in good health are included in such studies. This age-related decline of testosterone levels has been recently confirmed by a longitudinal study including a large number of subjects. The progressive decline begins early, from the late thirties, and continues at a constant rate throughout the subject’s lifetime. Since SHBG increases with age, free testosterone and non-SHBG-bound testosterone (referred to as bioavailable testosterone) decrease more markedly than total testosterone. As variations of SHBG levels (mainly a decrease in obese and/or insulin-resistant subjects) are often encountered in clinical practice and as it is difficult to reliably measure free testosterone, bioavailable testosterone appears to be the better index to diagnose androgen deficiency in the aging male. Elevation of basal LH levels, decrease of hCG-induced testosterone levels and reduction of Leydig cell number demonstrate the testicular origin of hypogonadism. However, gonadotropic function is also relatively altered with aging. As a result of this alteration of gonadotropic function, LH level is not a reliable index of hypogonadism in the aging male. None of the androgen-dependent functions that are altered with aging, i.e. libido, erectile function, sense of well-being, muscle mass, muscle strength, fat mass, bone mass, etc., are exclusively controlled by androgens. In clinical practice, the indication for androgen replacement therapy must therefore be based on a combination of clinical symptoms and a reduction of bioavailable testosterone below a certain cut-off value, indicating “significant” hypogonadism.     

Hormone treatments and preventive strategies in the aging male: whom and when to treat?

Sex hormones have a broad range of actions in regulating very diverse systems throughout life. Testosterone and other related hormones change with age to varying degrees and may induce pathophysiological changes and the clinical condition known as andropause. Androgen replacement is the accepted but not the only possible treatment for andropause. The presence of clinical symptoms, including a loss of sexual function, intellectual capacity, lean body mass, or bone mineral density; alterations in body hair, skin, or sleep pattern; or increases in visceral fat, together with low levels of serum testosterone characterize andropause. An appreciation of the potentially undesirable impact of androgens on the biology of prostate cancer, as well as possibly the cardiovascular system, is necessary. However, proper evaluation of aging men with symptoms of andropause will result in a decision to initiate androgen therapy in some aging men.