Relationship of Prostate -Specific Antigen to Age and Testosterone in Men With Type 2 Diabetes Mellitus

ObjectiveTo determine whether prostate-specific antigen (PSA) concentrations in type 2 diabetic men with hypogonadotrophic hypogonadism are lower than those in eugonadal men with type 2 diabetes and whether PSA concentrations are related to plasma testosterone concentrations.MethodsIn this cross-sectional study, we measured serum total testosterone, sex hormone–binding globulin, free testosterone, PSA, hematocrit, and hemoglobin A_1c in consecutive type 2 diabetic men who presented to 2 endocrinology referral centers between January 2006 and January 2007. We collected other clinical and demographic data including age, height, weight, and ethnicity.ResultsOf 400 eligible patients, 280 men met inclusion criteria. Plasma PSA concentrations were lower in type 2 diabetic men with low free testosterone concentrations than in those with normal free testosterone concentrations (25.65 ± 2.02 ng/dL vs 31.70 ± 2.31 ng/dL, P = .011). PSA concentrations were positively related to age (r = 0.34, P < .001), total testosterone (r = 0.29, P < .001), free testosterone (r = 0.17, P = .02), and sex hormone– binding globulin (r = 0.22, P < .001) and negatively related to body mass index (r = –0.28, P < .001). In stepwise backward regression analysis, PSA concentration was predicted by age (P < .001) and free testosterone (P < .001), but not by body mass index or sex hormone–binding globulin.ConclusionsPlasma PSA concentrations are lower in type 2 diabetic men with hypogonadism than in eugonadal men with type 2 diabetes, and plasma PSA is related to age, plasma total testosterone concentrations, and free testosterone concentrations in patients with type 2 diabetes. (Endocr Pract. 2008;14:1000-1005)     

Effect of Testosterone on Insulin Sensitivity in Men with Idiopathic Hypogonadotropic Hypogonadism

ObjectiveTo assess the presence of insulin resistance (IR) among a homogeneous cohort of male patients with idiopathic hypogonadotropic hypogonadism (IHH) and to investigate the effects of testosterone therapy on IR in this specific group.MethodsTwenty-four male patients with untreated IHH and 20 age-, sex-, and weight-matched eugonadal healthy control subjects were recruited for the study. Plasma glucose, plasma insulin, total and free testosterone, follicle-stimulating hormone, luteinizing hormone, estradiol, and sex hormone-binding globulin levels were measured in fasting blood samples, and biochemical and hormonal analyses were performed for all study participants. IR was calculated by the homeostasis model assessment of insulin resistance (HOMA-IR) formula and the quantitative insulin sensitivity check index (QUICKI). Body mass index was calculated by weighing and measuring the heights of all study participants at the beginning of the investigation. Body fat mass and body lean mass were calculated as percentages of body weight by bioelectrical impedance analysis of body composition. Sustanon 250 (a combination of 4 testosterones) was administered intramuscularly once every 3 weeks for 6 months to male patients with IHH after a basal anthropometric, biochemical, and hormonal evaluation. The response to therapy was monitored by regular clinical examinations and serum testosterone measurements. After 6 months of testosterone treatment, the entire anthropometric, biochemical, and hormonal evaluation was repeated 14 days after the last injection of testosterone.ResultsBefore treatment, male patients with IHH had higher fasting plasma glucose concentrations, higher fasting plasma insulin levels, a higher HOMA-IR score, and a lower QUICKI when compared with the control group. After testosterone treatment in the patient group, the HOMA-IR score decreased dramatically to the level in the control group. The high body fat mass of the male patients with IHH was reduced significantly after testosterone treatment, concomitant with significant increases in body mass index and body lean mass.ConclusionInsulin sensitivity improves and body fat mass decreases with long-term testosterone replacement therapy. (Endocr Pract. 2007;13:629-635)     

Treatment of Hypogonadism with Testosterone in Patients with Type 2 Diabetes Mellitus

ObjectiveTo investigate the effect of testosterone treatment on insulin resistance, glycemic control, and dyslipidemia in Asian Indian men with type 2 diabetes mellitus (T2DM) and hypogonadism.MethodsWe conducted a double-blind, placebo-controlled, crossover study in 22 men, 25 to 50 years old, with T2DM and hypogonadism. Patients were treated with intramuscularly administered testosterone (200 mg every 15 days) or placebo for 3 months in random order, followed by a washout period of 1 month before the alternative treatment phase. The primary outcomes were changes in fasting insulin sensitivity (as measured by homeostasis model assessment [HOMA] in those patients not receiving insulin), fasting blood glucose, and hemoglobin A1c. The secondary outcomes were changes in fasting lipids, blood pressure, body mass index, waist circumference, waist-to-hip ratio, and androgen deficiency symptoms. Statistical analysis was performed on the delta values, with the treatment effect of placebo compared with the effect of testosterone.ResultsTreatment with testosterone did not significantly influence insulin resistance measured by the HOMA index (mean treatment effect, 1.67 ± 4.29; confidence interval, -6.91 to 10.25; P > .05). Mean change in hemoglobin A1c (%) (-1.75 ± 5.35; -12.46 to 8.95) and fasting blood glucose (mg/dL) (20.20 ± 67.87; -115.54 to 155.94) also did not reach statistical significance. Testosterone treatment did not affect fasting lipids, blood pressure, and anthropometric determinations significantly.ConclusionIn this study, testosterone treatment showed a neutral effect on insulin resistance and glycemic control and failed to improve dyslipidemia, control blood pressure, or reduce visceral fat significantly in Asian Indian men with T2DM and hypogonadism. (Endocr Pract. 2010;16:570-576)     

Prevalence of Hypogonadism in Patients with Type 2 Diabetes Mellitus in an Asian Indian Study Group

ObjectiveTo determine the prevalence of hypogonadism in Asian Indian patients with type 2 diabetes mellitus (T2DM) and to correlate it with components of the metabolic syndrome and microvascular complications of T2DM.MethodsOne hundred consecutive male patients with T2DM between 25 and 50 years of age and 50 age-matched healthy adults without diabetes underwent assessment. Calculated free testosterone was derived by using serum total testosterone and sex hormone-binding globulin. Those patients with 2 calculated free testosterone values less than 64.8 pg/mL were diagnosed as having hypogonadism.ResultsOf the 100 patients with T2DM, 15 (15%) were found to have hypogonadism—7 of 29 (24%) between 31 and 40 years of age and 8 of 67 (12%) between 41 and 50 years old. None of the 4 patients between 25 and 30 years old had hypogonadism. Eleven patients (73%) had hypogonadotropic hypogonadism, and 4 (27%) had hypergonadotropic hypogonadism. Among the control subjects, the prevalence of hypogonadism was 10%. In comparison with Western data, we found a higher prevalence of hypogonadism in patients with T2DM, especially in those in the 4th decade of life. The prevalence of hypogonadism was higher in obese patients, although it did not reach statistical significance. No statistically significant correlation was observed between hypogonadism and age, duration of diabetes, glycemic control, androgen deficiency symptoms, or microvascular complications.ConclusionThe prevalence of hypogonadism was higher in the patients with diabetes than in the control subjects, although the difference did not reach statistical significance. There was no correlation of hypogonadism with components of the metabolic syndrome or microvascular complications of diabetes mellitus. (Endocr Pract. 2009;15:513-520)     

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)     

Low Testosterone Levels are Frequent in Patients with Acute Respiratory Failure and Are Associated with Poor Outcomes

ObjectiveLow testosterone level is a common finding in critically ill patients with trauma, shock, and sepsis. However, its prevalence and outcomes in patients with primary acute respiratory failure is unknown; low testosterone could contribute to respiratory muscle weakness and further compromise ventilation in these patients.MethodsWe aimed to determine the prevalence, severity, and effects of hypotestosteronemia in patients with acute respiratory failure in a 16-bed single academic center medical intensive care unit (ICU). We studied 30 men who required mechanical ventilation for ≥ 24 hours for a primary diagnosis of acute respiratory failure. Blood samples were drawn on ICU day 1 and day 3 to measure serum levels of total and free testosterone.ResultsHypotestosteronemia (level below the lower reference limit) was present on day 1 in 93.1% (total testosterone) and 76.7% (free testosterone) of patients and on day 3 in 94.4% (total testosterone) and 100% (free testosterone) of patients. Sex hormone–binding globulin, dehydroepiandrosterone sulfate, follicle-stimulating hormone, luteinizing hormone, and thyroid function levels were all within stated reference ranges. Total and free testosterone levels correlated inversely with ventilator days and ICU length of stay.ConclusionHypotestosteronemia is common in mechanically ventilated patients with primary acute respiratory failure and may contribute to longer ICU stay. Further studies are needed to determine the effect of testosterone replacement on short- and long-term outcomes in these patients. (Endocr Pract. 2014;20:1057-1063)     

Are There Variances Of Calculated Free Testosterone Attributed To Variations In Albumin And Sex Hormone-Binding Globulin Concentrations In Men?

ObjectiveCalculated free testosterone (cFT) is determined from total testosterone (TT), sex hormone binding globulin (SHBG), and albumin (Alb) levels using mathematical formulae. Variations in cFT due to changes in SHBG or Alb have not been investigated. We evaluated potential cFT variances determined with fixed Alb (4.3 g/dL) and measured Alb, and the point at which low SHBG and Alb combinations produced significant cFT variance.MethodWe analyzed 11,176 data points from 5,797 men. cFT values with fixed versus actual Alb values were evaluated and compared. cFT levels were theoretically determined for all possible combinations of TT, SHBG, and Alb (8,343,552 combinations). Agreement between the 2 measures was assessed with Lin’s concordance coefficient.ResultsMean Alb was 4.06 ± 0.32 g/dL. Mean SHBG was 39.0 ± 23.6 nmol/L. A fixed Alb of 4.3 g/dL did not produce significant variance for most cFT evaluations. Accuracy decreased when Alb was ≤3.5 g/dL in combination with SHBG ≤30 nmol/L, and this occurred in 1.2% of all data points.ConclusionA fixed Alb of 4.3 g/dL is acceptable for most clinical evaluations. If Alb is <3.5 g/dL and SHBG is <30 nmol/L, the variance increases, and a free testosterone (FT) measurement by equilibrium dialysis is warranted for better accuracy. (Endocr Pract. 2013;19:236-242)     

Effects of Bisphosphonates on Bone of Osteoporotic Men With Different Androgen Levels: A Case-Control Study

ObjectiveOsteoporosis in men has been neglected despite its association with disability and mortality. We evaluated the effect of bisphosphonates (BPs) on bone mineral density (BMD) and bone turnover biomarkers of osteoporotic men with different androgen levels.MethodsThis case-control study included 136 osteoporotic men who were divided into normal group (n = 75) and hypogonadism group (n = 61) (patients treated with testosterone were excluded) according to their serum testosterone levels (cutoff value, 350 ng/dL). BMD, serum testosterone, total alkaline phosphatase, and cross-linked C-telopeptide of type I collagen were detected. The relationship between testosterone levels and BMD at baseline was evaluated. All patients were treated with BPs for 2 years. We compared the effects of BPs on BMD and bone turnover biomarkers between the 2 groups.ResultsAt baseline, there were no significant differences in BMD and bone turnover biomarkers between the 2 groups. Testosterone levels were positively correlated with BMD in the hypogonadism group. After treatment, the lumbar BMD increased by 7.65% ± 1.54% and 7.47% ± 1.88% in normal and hypogonadism groups, respectively (both P < .01 vs baseline) and hip BMD increased without significant differences between the 2 groups. Serum cross-linked C-telopeptide of type I collagen and alkaline phosphatase levels decreased without significant differences between the 2 groups (all P < .01 vs baseline).ConclusionTestosterone level is positively correlated with BMD in men with hypogonadism. In osteoporotic men, BPs significantly increase spine and hip BMD and decrease bone resorption. The efficacy of BPs is similar in men with or without hypogonadism.     

High Prevalence of Prolonged QT Interval in Obese Hypogonadal Males

Obese subjects show several electrocardiographic alterations, including prolonged QT interval, a marker for fatal cardiac arrhythmias. Prolonged QT interval has recently been linked to low testosterone levels, a frequent occurrence in male obese patients but no study has yet assessed whether hypoandrogenism contributes to QT interval prolongation in this population. Aim of this study was to evaluate whether prolonged QT interval is linked to hypogonadism in male obese subjects. QT interval corrected for heart rate (QTc) was measured from standard electrocardiogram recordings in 136 obese men (BMI 30 >kg/m², range 30.1–75.4 kg/m²). Obese men were classified as eugonadal or hypogonadal according to serum total testosterone levels (i.e., greater or less than 9.9 nmol/l). Our study showed that QTc measurements corrected by either Bazett (419 ± 3.2 vs. 408 ± 3.4 ms, P < 0.05), Fridericia (406.3 ± 3.39 vs. 396.4 ± 3.03 ms, P < 0.05) or Hodges (407.0 ± 3.12 vs. 397.3 ± 2.84 ms, P < 0.05) were longer in hypogonadal compared with eugonadal obese men; further, prolonged QTc interval (i.e., >440 ms) was more frequent among hypogonadal compared with eugonadal obese men (23% vs. 10%, P < 0.05). The degree of weight excess, diabetes, sleep apnoea and potassium levels were not associated with prolonged QTc. In conclusion, obese hypogonadal men show a greater prevalence of prolonged QT interval compared with their eugonadal counterparts. It appears therefore that low levels of testosterone in obese men may contribute to the arrhythmogenic profile of these patients, a heretofore unknown link which warrants further clinical attention.     

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)     

Testosterone Levels Achieved by Medically Treated Transgender Women in a United States Endocrinology Clinic Cohort

Objective: Most transgender women depend on medical treatment alone to lower testosterone levels in order to align physical appearance with gender identity. The medical regimen in the United States typically includes spironolactone and estrogens. The purpose of this cross-sectional study was to assess the testosterone suppression achieved among transgender women treated with spironolactone and estrogens.Methods: Testosterone and estradiol levels were extracted from the electronic medical records of 98 anonymized transgender women treated with oral spironolactone and oral estrogen therapy at the Endocrinology Clinic at Boston Medical Center.Results: Patients starting therapy required about 9 months to reach a steady-state testosterone, with significant heterogeneity of levels achieved among patients. Patients with normal body mass index (BMI) had higher testosterone levels, whereas patients with obese BMI had lower testosterone levels throughout treatment. Stratification of patients by age or spironolactone dosage revealed no significant difference in testosterone levels achieved. At steady state, patients in the highest suppressing quartile were able to achieve testosterone levels of 27 ng/dL, with a standard deviation of 21 ng/dL. Measured serum estradiol levels did not change over time and did not correlate with dosage of estradiol administered.Conclusion: Among a cohort of transgender women treated with spironolactone and estrogen, the highest suppressing quartile could reliably achieve testosterone levels in the female range at virtually all times. The second highest suppressing quartile could not achieve female levels but remained below the male range virtually all of the time. One quartile was unable to achieve any significant suppression.Abbreviations:BMC = Boston Medical CenterBMI = body mass indexCPY = cyproterone acetateLC-MS/MS = liquid chromatography–tandem mass spectrometryQ = quartile     

Genetically Predicted Testosterone and Systemic Inflammation in Men: A Separate-Sample Mendelian Randomization Analysis in Older Chinese Men

ObjectivesObservationally, testosterone is negatively associated with systemic inflammation, but this association is open to both residual confounding and reverse causality. Large-scale randomized controlled trials (RCTs), assessing exogenous effects, are presently unavailable. We examined the association of endogenous testosterone with well-established systemic inflammatory markers (white blood cell, granulocyte, lymphocyte and high-sensitivity C-reactive protein (hsCRP)) using a separate-sample Mendelian randomization analysis to minimize reverse causality.MethodsA genetic prediction rule for serum testosterone was developed in 289 young Chinese men with mean age of 21.0, using selected testosterone-related SNPs (rs10046, rs1008805 and rs1256031). Multivariable linear regression was used to examine the association of genetically predicted serum testosterone with inflammatory markers among 4,212 older Chinese men from the Guangzhou Biobank Cohort Study.ResultsGenetically predicted testosterone was unrelated to white blood cell count (-0.01 109/L per nmol/L testosterone, 95% confidence interval (CI) -0.05 to 0.04), granulocyte count (-0.02 109/L, 95% CI -0.06 to 0.02), lymphocyte count (0.005 109/L, 95% CI -0.01 to 0.02) and hsCRP (-0.05 mg/L, 95% CI -0.15 to 0.06).ConclusionOur findings did not corroborate any anti-inflammatory effects of testosterone or corresponding potentially protective effects of testosterone on chronic diseases resulting from reduced low-grade systemic inflammation.     

Sexual Precocity in A 2-Year-Old Boy Caused by Indirect Exposure to Testosterone Cream

ObjectiveTo report a rare case of sexual precocity caused by inadvertent exposure to testosterone cream.MethodsWe report the clinical, laboratory, and radiologic findings of a boy presenting with sexual precocity; review short- and long-term consequences; and discuss preventative measures.ResultsA₂ and 7/12-year-old boy had onset of pubic hair without testicular enlargement and a period of rapid linear growth. History revealed possible topical testosterone exposure from close contact with the child’s father. On physical examination, the boy had Tanner stage II pubic hair distribution. Laboratory evaluation findings were normal for age except for the testosterone concentration, which was comparable to late-pubertal and adult male levels at 371 ng/dL (reference range, < 3-10 ng/dL for prepubertal male). Brain magnetic resonance imaging and testicular ultrasonography were normal. Skeletal age was advanced at age 4 and 6/12 years. Repeated laboratory evaluation, after the child’s father ceased testosterone use, revealed a normal testosterone concentration of 10 ng/dL. Thus, this boy’s sexual precocity was attributed to inadvertent exogenous androgen exposure.ConclusionsWhen examining a child with sexual precocity, asking about possible exposure to androgens and estrogens is important. Patients being treated with these products should be educated about the possible risks of testosterone exposure to others and ways to limit exposure. (Endocr Pract. 2008;14:1027-1030)     

46,XX SRY-Positive Male Syndrome Presenting with Primary Hypogonadism in the Setting of Scleroderma

ObjectiveTo describe a case of SRY gene translocation in a man with scleroderma presenting with primary hypogonadism.MethodsWe present the clinical, physical, laboratory, and pathologic findings of the study patient and discuss the cytogenetic analysis and the cause of the sexual dysfunction. Relevant literature is reviewed.ResultsA 35-year-old man with a recent diagnosis of diffuse cutaneous sclerosis was referred by his rheumatologist because of a low testosterone level. His medical history was notable for right cryptorchidism corrected after birth. He had no history of sexual activity, but reported normal erectile function before his current presentation. Physical examination findings were remarkable for a height of 157.5 cm; weight of 72.7 kg; extensive, diffuse thickening of the skin; mild gynecomastia; little axillary and pubic hair; and soft testes (1-2 mL bilaterally). Initial laboratory testing revealed the following values: follicle-stimulating hormone, 22.1 mIU/mL (reference range, 1.4-18.1 mIU/mL); luteinizing hormone, 19.7 mIU/mL (reference range, 1.5-9.3 mIU/mL); total testosterone, 25 ng/dL (reference range, 241-827 ng/dL); and free direct testosterone, 0.8 pg/mL (reference range, 8.7-25.1 pg/mL). Laboratory test results were consistent with primary hypogonadism. A urologist performed testicular biopsy, which showed severe testicular atrophy with absent spermatogenesis. Primary hypogonadism due to Klinefelter syndrome or testicular fibrosis secondary to scleroderma was suspected. Karyotype analysis showed a 46,XX karyotype, and fluorescence in situ hybridization was consistent with a 46,XX,Xp22.3(SRY +) gene translocation. After a normal prostate-specific antigen level was documented, testosterone replacement therapy was initiated, and he was referred for genetic counseling.ConclusionsThe 46,XX SRY-positive male syndrome is rare. Adult diagnosis can be challenging because of normal sexual development. Scleroderma, which rarely can occur in Klinefelter-type syndromes, further complicated the diagnosis in this case. (Endocr Pract. 2011;17:95-98)     

Analyse de l’algorithme décisionnel basé sur la testostérone totale et recommandé pour le diagnostic de l’hypogonadisme acquis

Introduction

The diagnosis of acquired hypogonadism is still an important issue for laboratory medicine. Hypogonadism is defined as a sustained decrease of total testosterone confirmed by the biochemistry laboratory and total testosterone measurement is proposed as the initial step in the investigation of hypogonadism. If TT is over 12 nmol/l, the probability of hypogonadism is considered low and it is suggested that patients be referred to others methods of investigation. Only a small percentage of men aged 50 and over are treated for hypogonadism. Seventy percent of men investigated for hypogonadism have a TT of over 12 nmol/l and there is an unpredictable increase of SHBG during this period, reducing the bioavailability of circulating testosterone. The hypothalamic-pituitary gonadal axis is modified with age and contributes to hypogonadism. The efficacy of biochemical investigation of hypogonadism needs to be reassessed.

Materials and methods

Total testosterone and LH were measured on the Centaur immunoanalyser (Siemens) and SHBG was analysed on the Immulite 2000 (Siemens). Bioavailable testosterone was calculated using the formula provided by ISSAM.

Results

Using the algorithm based on TT, only 27.9% of men would have been investigated for hypogonadism. Of the 638 patients considered as normal, 325 showed an index of hypothalamic-pituitary gonadal axis stimulation and possible hypogonadism, revealed by an elevated LH. In these patients with TT superior to 12 nmol/l and a LH superior to 7 UI/l, SHBG level was at the upper limit of or over the reference range. No correlation was observed between calculated BT and the abnormal LH level found in these patients. Calculated BT was not considered a good marker of hypogonadism for these patients.

Conclusion

Elevated LH is a biochemical marker of hypogonadism and should be interpreted in the context of stimulation of the hypothalamic-pituitary gonadal axis. Based on our data, an initial step in the investigation of hypogonadism based only on TT does not seem suitable for the identification of all patients who might experience hypogonadism. A complete investigation should be offered to all patients with clinical evidence of hypogonadism whatever their TT level. In patients who might benefit from hormonal treatment, calculated BT should be interpreted with caution. A definition of hypogonadism based on TT does not seem appropriate and a new definition based on bioavailable testosterone and the hypothalamopituitary gonadal axis should be considered.     

Pituitary Evaluation in Patients with Low Prostate-Specific Antigen

Objective: To evaluate pituitary function in men with a low screening prostate-specific antigen (PSA) of ≤0.1 ng/mL and test the hypothesis that low PSA is associated with hypogonadism alone or other hormone deficiency.Methods: This was a case-control study evaluating the rates of hypogonadism and low insulin-like growth factor (IGF)-1 in a cohort of men with low or normal screening PSA level. Sixty-four men >40 years old without known prostate disease were divided into a low-PSA group (PSA ≤0.1 ng/mL) and normal-PSA group (PSA 1 to 4 ng/mL). Hormonal evaluation included total testosterone, prolactin, luteinizing hormone, follicle-stimulating hormone, IGF-1, growth hormone, thyroid-stimulating hormone, free thyroxine, morning cortisol, and adrenocorticotropic hormone. The difference between each patient's observed IGF-1 and the IGF-1 age-specific lower limit was calculated. The odds ratios (ORs) for having hypogonadism and associated 95% confidence intervals (CIs) were calculated using the Cochran-Mantel-Haenszel test.Results: The rate of hypogonadism was significantly higher in the low-PSA group (n = 44) compared with the normal-PSA control group (n = 20) (45.5% vs. 15.0%; OR, 4.7; 95% CI, 1.2 to 18.4; P = .027). The total testosterone in the low-PSA group was significantly lower compared with the control group (181.7 ng/dL vs. 263.7 ng/dL; P = .008). IGF-1 values were below their lower bound in 18.6% of subjects in the low-PSA group, compared with 0% in the control group.Conclusion: Men with low PSA have significantly higher rates of hypogonadism and low IGF-1 compared with those with normal PSA. In such men, we recommend hormonal evaluation to exclude associated pituitary dysfunction.Abbreviations: BMI = body mass index; GH = growth hormone; IGF-1 = insulin-like growth factor 1; MRI = magnetic resonance imaging; PSA = prostate-specific antigen; T2DM = type 2 diabetes mellitus; VA-NWIHCS = VA-Nebraska Western Iowa Health Care System     

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.     

Estrogen Levels Do Not Rise With Testosterone Treatment For Transgender Men

Objective: Existing transgender treatment guidelines suggest that for transmasculine treatment, there is a possible need for estrogen-lowering strategies adjunct to testosterone therapy. Further, guidelines advocate consideration of prophylactic female reproductive tissue surgeries for transgender men to avoid the possibility of estrogen-related health risks. Despite the paucity of objective data, some transgender men seek conversion inhibitors. We sought to determine estradiol levels in transgender men treated with testosterone therapy and the change in those levels with treatment, if any.Methods: Estradiol levels were extracted from the electronic medical records of 34 anonymized transgender men treated with testosterone therapy at the Endocrinology Clinic at Boston Medical Center. Data were sufficient to observe 6 years of follow-up.Results: With increased testosterone levels in trans-gender men, a significant decrease in estradiol levels was noted. There was a significant negative correlation between testosterone levels and body mass index, which may serve to explain part of the mechanism for the fall in estradiol levels. Even though the fall in estradiol levels was significant statistically, the actual levels remained within the normal male range, even with 6 years of follow-up.Conclusion: These data suggest that when exogenous testosterone is used to achieve normal serum male testosterone levels for transgender men, it is converted to normal male levels of estradiol, with some decline in those estradiol levels that might be attributable to a fall in fat mass. There appears to be no role for aromatase conversion inhibitors or other estrogen-reducing strategies in trans-gender men.Abbreviation: BMI = body mass index     

Corticotropin-Independent Cushing Syndrome in a Child With an Ovarian Tumor Misdiagnosed as Nonclassic Congenital Adrenal Hyperplasia

ObjectiveTo describe a patient with corticotropinindependent Cushing syndrome previously diagnosed and treated as congenital adrenal hyperplasia (CAH).MethodsWe describe the initial manifestations, clinical investigations, and postoperative follow-up of the patient and review similar cases in the literature.ResultsA 5 and 9/12-year-old girl who was initially diagnosed and treated as having CAH and was noncompliant with glucocorticoid therapy presented with weight gain, hypertension, and a mass in the lower abdomen. On physical examination, she was a cushingoid-appearing girl with proximal muscle weakness and notable facial acne. Laboratory findings included elevated serum testosterone, 17-hydroxyprogesterone, dehydroepiandrosterone sulfate, androstenedione, estradiol, and cortisol, as well as elevated urinary cortisol and cortisone. Serum corticotropin was undetectable. She had normal serum electrolytes and plasma renin activity. Computed tomography scan of the abdomen and pelvis showed a cystic mass with a focal enhancing solid component arising from the right ovary, which was subsequently determined to be a steroid cell tumor not otherwise specified.ConclusionAlthough ovarian steroid cell tumors typically secrete gonadal steroids, the rare steroid cell tumors not otherwise specified can secrete both glucocorticoids and gonadal steroids and are an unusual cause of Cushing syndrome. (Endocr Pract. 2008;14:875-879)