The prostate is the site of two common diseases in aging men, benign prostatic hyperplasia and prostate cancer (PCa). Epidemiological studies show that, in the United States, PCa accounts for 28.7% of new non-skin cancers and 12.7% of cancer-related deaths.1 Androgen deprivation therapy (ADT) retards PCa progression in 60%–80% of patients but may cause cardiovascular complications and alterations in body composition, lipoprotein metabolism, and sexual function. In general, ADT may result in a decreased quality of life. Furthermore, studies in men demonstrate that low serum testosterone (T) levels are associated with several cardiovascular risk factors,2,3 such as lower high density lipoprotein cholesterol, higher triglyceride concentrations, hyperinsulinemia, and increased abdominal adiposity. These factors are all characteristic of the metabolic insulin resistance syndrome. In addition, many patients treated with ADT experience rapid bone loss that increases the risk of debilitating osteoporotic fractures.4–6 Reports indicate that total and free levels of serum T decline in aging men and that abdominal visceral fat is inversely associated with T levels. Resting energy expenditure (REE), which accounts for 60%–70% of total daily energy expenditure, decreases with age, physical inactivity, sympathetic nervous system and endocrine status.7,8 To our knowledge, the effects of ADT on REE have not been fully explored in controlled trials. The goal of this prospective study was to determine the effects of ADT on body composition and resting metabolic rate in patients with metastatic PCa.

Sixteen men, aged 63 to 96 years (mean age 71), with untreated metastatic PCa were enrolled in this study.

Prior to orchiectomy, all patients were evaluated clinically and by laboratory analysis to establish a baseline. After a careful medical history had been taken from each patient, we assessed several exclusion criteria, namely, cognitive alterations, depression and emotional liability.

Laboratory examinations included tests of FSH-LH serum concentrations, and an evaluation of body mass index, fat/lean body mass, bone mineral density, carbohydrate/lipid oxidation, and resting energy expenditure.

Following orchiectomy, the same evaluation was carried out monthly and after 12 months, the period chosen for final analysis.

To evaluate body composition, all patients underwent densitometry testing (dual-energy X ray absorptiometry - DEXA).9 The REE, fat and carbohydrate oxidation levels were measured using indirect calorimetry, with a Delta-TRAC Metabolic Monitor.10 Body composition analyses and indirect calorimetry were carried out at baseline and after 12 months following the orchiectomy procedure.

Written consent was obtained from all patients, and this protocol was approved by the Ethics Committee at our institution.

Statistically significant differences in body composition pre and post orchiectomy were seen in terms of weight, body mass index (BMI) and lean body mass (LBM). Total fat body mass (FBM) exhibited a tendency to increase but failed to reach significance. No significant changes were observed in bone mineral density (BMD) and REE, but we identified a statistically significant change in terms of increased carbohydrate oxidation (CHOox) and a decrease in lipid oxidation (LIPIDox). These results are listed in Table 1.

Aging is associated with sarcopenia (loss of muscle mass), with an average 12 kg loss of LBM between the ages of 25 and 70 years and an increase in FBM of 18%–36% during the same period.2 Testosterone levels exhibit a positive correlation with LBM and a negative correlation with FBM. This has led to the hypothesis that ADT may help mitigate age-related alterations in body composition.

Our study reports two major findings: 1) ADT was associated with decreased body weight and with decreased LBM; 2) ADT led to increased CHOox and decreased LIPIDox.

Androgens modulate body composition, including lipid and protein metabolism.12 Smith et al,13 Galvão et al,14 Levy et al,15 and Van Londen et al16 observed significant changes in metabolic and body composition parameters after 6 months of induced hypogonadism in all patients. These studies included 22, 72, 35 and 81 men, respectively. The researchers observed a significant increase in FBM (20.2±9.4 to 21.9±9.6 kg,13 13.8±2.3%,14 1.17±2.3 %,15 and 2167.15 g,16 respectively) and a significant decrease in LBM (63.2±8.0 to 62.3±5.4 Kg,13 −2.4 ± 0.4%,14 −1.15±2.20%;15 and −1785.81 g,16 respectively) with no significant changes in total body weight, lipid readings or glucose metabolism.

They also reported a positive correlation between the changes in FBM and insulin concentrations (r=0.56; p=0.013). These results are in agreement with other studies that demonstrated a relationship between T and abnormalities in carbohydrate and lipid metabolism.17 In healthy male populations, low T concentrations are negatively correlated with the degree of central abdominal obesity. In hypogonadal males, there is a tendency toward increased visceral adiposity and reduced muscle mass that can be reversed by androgen replacement.18 The underlying mechanisms for these observations are not well defined, but androgen receptors are known to be present on visceral adipocytes. It is likely that T is directly involved in the mobilization of free fatty acids.19

We observed significant changes in metabolic and body composition in our patients after ADT. We identified significant decreases in total body weight, BMI and LBM (2.5 kg, p = 0.01; −0.8 kg/cm2, p = 0.02, −11.7 kg, p = 0.002, respectively). FBM was found to increase (7.15 kg, p = 0.06) with no significant change in bone mineral density (BMG). There were no changes in REE, but we did identify a significant increase in CHOox and a decrease in LIPIDox (52.62%, −4.10% respectively). In one study, suppression of T levels after 10 weeks of GnRH agonist administration was found to reduce REE in young men. In this study, researchers were unable to determine whether the effect was directly mediated by a reduction in T levels or if it was due to a subsequent reduction in T aromatization to estrogen.20 We were unable to show alterations in REE in our study, possibly due to the size of our study sample. The altered concentrations of gonadotropins following orchiectomy may be linked with the effects of this procedure on the pituitary gland. It is possible that other pituitary hormones (growth hormone) are also affected. This in turn may contribute to the observed changes in body composition. It is important to consider that ADT not only acts on PCa but also affects metabolism, including hematogenesis, bone, fat, protein, and sarcho-metabolism. Despite PCa being one of the leading causes of death, a substantial proportion of aging patients die of unrelated causes that are due to comorbidities, often in the context of metabolic syndrome.

The present study has several strengths and some limitations. To our knowledge, this is the first prospective study to examine changes in body composition, resting energy expenditure, and consequences involving the oxidation of carbohydrates and lipids in the context of ADT.

A study on a larger group of patients would be of great interest once a limited number of patients included from only one centre may be considered a limitation in this study.

After 12 months of androgen deprivation therapy, elderly males with metastatic prostate cancer exhibit declines in lean body mass and lipid oxidation, together with an increase in carbohydrate oxidation.