The role of testosterone replacement therapy following radical prostatectomy.

Hypogonadism is associated with a decreased serum testosterone level and numerous signs and symptoms, such as decreased libido, erectile dysfunction, decreased muscle mass, increased fat deposition, decreased ability to concentrate, and decreased bone mineral density Unlike women, who have a sudden loss of estrogen during menopause, men experience a gradual 1% to 2% decline in testosterone every year starting at age 30. There are several reasons for decreasing testosterone levels with age. As men age, they have a decline in Leydig cell numbers (primary failure), a decrease in gonadotropin-releasing hormone pulse amplitude (secondary failure), and an increase in sex hormone-binding globulin, all of which result in the reduction of available free or total testosterone Testosterone replacement therapy (TRT) is effective in treating the signs and symptoms of hypogonadism. These benefits include improvements in sexual function, muscle mass and strength, fat distribution, bone density, cognition, and mood Hypogonadism occurs frequently among men who have prostate cancer. Yamamoto and colleagues The association between testosterone replacement therapy and the development of prostate cancer In 1941, Huggins and Hodges [14] first demonstrated that a reduction in testosterone by castration caused metastatic prostate cancer to regress and that administration of exogenous testosterone promoted prostate cancer growth; however, current data have demonstrated that low testosterone levels are more likely to be associated with prostate cance

Delivering Enhanced Testosterone Replacement Therapy through Nanochannels

Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/110712/1/adhm201400348.pdfhttp://deepblue.lib.umich.edu/bitstream/2027.42/110712/2/adhm201400348-sup-0001-S1.pd

Effect of 12 months of testosterone replacement therapy on metabolic syndrome components in hypogonadal men: data from the Testim Registry in the US (TRiUS)

<p>Abstract</p> <p>Background</p> <p>Recent evidence suggests that there may be a bidirectional, physiological link between hypogonadism and metabolic syndrome (MetS), and testosterone replacement therapy (TRT) has been shown to improve some symptoms of MetS in small patient populations. We examined the effect of 12 months of TRT on MetS components in a large cohort of hypogonadal men.</p> <p>Methods</p> <p>Data were obtained from TRiUS (Testim^®Registry in the United States), a 12-month, multicenter, prospective observational registry (N = 849) of hypogonadal men prescribed Testim 1% testosterone gel (5-10 g/day). Data analyzed included age, total testosterone (TT), free testosterone (FT), sex hormone-binding globulin (SHBG), and MetS components: waist circumference, blood pressure, fasting blood glucose, plasma triglycerides, and HDL cholesterol.</p> <p>Results</p> <p>Of evaluable patients (581/849) at baseline, 37% were MetS+ (n = 213) and 63% were MetS- (n = 368). MetS+ patients had significantly lower TT (p < 0.0001) and SHBG (p = 0.01) levels. Patients with the lowest quartile TT levels (<206 ng/dL [<7.1 nmol/L]) had a significantly increased risk of MetS+ classification vs those with highest quartile TT levels (≥331 ng/dL [≥11.5 nmol/L]) (odds ratio 2.66; 95% CI, 1.60 to 4.43). After 12 months of TRT, TT levels significantly increased in all patients (p < 0.005). Despite having similar TT levels after TRT, only MetS+ patients demonstrated significant decreases in waist circumference, fasting blood glucose levels, and blood pressure; lowest TT quartile patients demonstrated significant decreases in waist circumference and fasting blood glucose. Neither HDL cholesterol nor triglyceride levels changed significantly in either patient population.</p> <p>Conclusion</p> <p>Hypogonadal MetS+ patients were more likely than their MetS- counterparts to have lower baseline TT levels and present with more comorbid conditions. MetS+ patients and those in the lowest TT quartile showed improvement in some metabolic syndrome components after 12 months of TRT. While it is currently unclear if further cardiometabolic benefit can be seen with longer TRT use in this population, testing for low testosterone may be warranted in MetS+ men with hypogonadal symptoms.</p

Controversies in testosterone supplementation therapy

Testosterone has now become one of the most widely used medications throughout the world. The rapid growth of the testosterone market in the past 10 years is due to many factors. We currently have a worldwide aging population. In the US, the number of men 65 years old or older is increasing 2-3 times faster than the number of men younger than 65 years. In addition, poor general health and certain medical conditions such as diabetes/metabolic syndrome (MetS), cardiovascular disease (CVD), and osteoporosis have been associated with low serum testosterone levels. [1],[2],[3] There are now fewer concerns regarding the development of prostate cancer (PCa) after testosterone therapy, making it a more attractive treatment option. Finally, the introduction of different forms of testosterone supplementation therapy (TST) with increased promotion, marketing, and direct-to-consumer advertising is also driving market growth. As the demand for TST continues to grow, it is becoming more important for clinicians to understand how to diagnose and treat patients with low testosterone

Physiological normal levels of androgen inhibit proliferation of prostate cancer cells in vitro

For more than 70 years, it has been believed that a severe reduction of serum androgen levels caused regression of prostate cancer (PCa) and that increasing androgen levels enhanced growth of PCa. However, numerous recent studies have questioned this traditional belief. In our study, LNCaP and MDA PCa 2b PCa cells were treated with various levels of androgens for 10 or 20 days, and the cell growth was measured with crystal violet mitogenic assay. The results indicated that the effect of androgens on the proliferation of PCa cells occurs in a biphasic pattern, with the androgen levels promoting optimal cell growth at approximately 0.23 ng ml−1 for LNCaP cells and between 1 and 2 ng ml−1 for MDA PCa 2b cells. Both of the optimal androgen levels are within the adult men's physiological low range (<2.4 ng ml−1 ). At lower concentrations than the optimal androgen level, increasing androgen concentration promoted the proliferation of PCa cells. However, at the higher concentrations, increasing androgen concentration resulted in a dose-dependent proliferative inhibition. We conclude that physiologically normal levels of androgen inhibit the proliferation of PCa cells in vitro. However, at very low levels androgens are essential for initial growth of PCa cells

Combined tests of PSA and testosterone will improve diagnosis and monitoring the progression of prostate cancer

Prostate-specific antigen (PSA) testing has been widely used to screen men for prostate cancer (PCa) and to monitor PCa progression. However, more studies have shown that around 15% of men with low or normal PSA levels have PCa. In this study, we aimed to investigate the relationship of androgen and PSA levels and to better understand the reason that some PCa patients have low serum PSA values. The in vitro data demonstrated that cultured LNCaP cells ceased to produce PSA after androgen withdrawal and resumed PSA production after androgen was re-added. The in vivo experiment results showed that 48% of PCa xenografts carrying mice have serum PSA level lower than 4 ng ml−1 . The serum PSA levels increased significantly with rises in testosterone (T) levels 1 week after T pellet implantation. These data indicated that the androgen is a key factor controlling the production of PSA. Low serum PSA levels in mice with PCa xenografts are associated with low serum T levels. Raising serum T levels in tumor caring mice will also significantly increase serum PSA level. This may have clinical implications when screening PSA in men, who have occult PCa

Testosterone inhibits the growth of prostate cancer xenografts in nude mice

Abstract Background Traditional beliefs of androgen’s stimulating effects on the growth of prostate cancer (PCa) have been challenged in recent years. Our previous in vitro study indicated that physiological normal levels of androgens inhibited the proliferation of PCa cells. In this in vivo study, the ability of testosterone (T) to inhibit PCa growth was assessed by testing the tumor incidence rate and tumor growth rate of PCa xenografts on nude mice. Methods Different serum testosterone levels were manipulated in male nude/nude athymic mice by orchiectomy or inserting different dosages of T pellets subcutaneously. PCa cells were injected subcutaneously to nude mice and tumor incidence rate and tumor growth rate of PCa xenografts were tested. Results The data demonstrated that low levels of serum T resulted in the highest PCa incidence rate (50%). This PCa incidence rate in mice with low T levels was significantly higher than that in mice treated with higher doses of T (24%, P < 0.01) and mice that underwent orchiectomy (8%, P < 0.001). Mice that had low serum T levels had the shortest tumor volume doubling time (112 h). This doubling time was significantly shorter than that in the high dose 5 mg T arm (158 h, P < 0.001) and in the orchiectomy arm (468 h, P < 0.001). Conclusion These results indicated that low T levels are optimal for PCa cell growth. Castrate T levels, as seen after orchiectomy, are not sufficient to support PCa cell growth. Higher levels of serum T inhibited PCa cell growth

An Update on Regenerative Medicine Clinical Trials in Erectile Dysfunction: Have We Made Any Progress?

Regenerative cell-based therapy for erectile dysfunction is probably safe, and may be functionally beneficial. Currently, phase 2 trials are under way that we hope will provide a better insight into the efficacy of this regenerative therapy.status: publishe