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     

Differential Endocrine and Metabolic Effects of Testosterone Suppressive Agents in Transgender Women

Objective: Suppression of testosterone secretion and/or action in transgender women using cyproterone acetate (CPA), spironolactone, or gonadotropin-releasing hormone analogues (GA) is achieved through various mechanisms. Our objective was to characterize possible differential effects of these compounds on metabolic and endocrine variables.Methods: We conducted a historic cohort study of transgender patients treated in a tertiary referral center. A longitudinal analysis of treatment naïve patients and a cross-sectional analysis of the whole cohort at the last visit was carried out.Results: Among 126 transgender women (75 treatment-naïve), CPA was the predominant androgen suppressive therapy (70%), followed by spironolactone (17.6%), and GA (10.2%). Among those who were treatment-naïve, the increase in serum prolactin levels over baseline was greater at 3 months following CPA initiation (mean change 397 ± 335 mIU/L) than following spironolactone (20.1 ± 87 mIU/L) or GA initiation (64.6 ± 268 mIU/L; P = .0002). Prolactin levels remained higher in the CPA-treated group throughout follow-up, irrespective of estradiol levels, which were similar between the groups. A worse metabolic profile was associated with treatment with CPA than with spironolactone or GA. In the CPA compared to the spironolactone and GA groups, high-density lipoprotein-cholesterol levels were lower (47.1 ± 10.4, 54.4 ± 12.2, and 60.3 ± 13, respectively; P = .0076), while body mass index levels (24.3 ± 5, 21.7 ± 2.3, and 20.7 ± 3.1 kg/m²; P = .03), and systolic (117 ± 12.1, 109 ± 12.2, and 105 ± 13.3 mm Hg; P = .01) and diastolic (74 ± 9, 65.6 ± 5.5, and 65.4 ± 11 mm Hg; P = .0008) blood pressure levels were higher at the last visit.Conclusion: Treatment of transgender women with CPA was associated with hyperprolactinemia and a worse cardiovascular risk profile than treatment with spironolactone or GA.Abbreviations: BMI = body mass index; CPA = cyproterone acetate; E2 = estradiol; FSH = follicle-stimulating hormone; GA = gonadotropin-releasing hormone analogues; LH = luteinizing hormone     

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     

A Review of Breast Development in Cisgender Women and Implications for Transgender Women

Objective: The objective of this article is to describe the hormonal pathways required for breast development in cisgender women and to review the current available literature describing breast growth and breast cancer risk in transgender women.Methods: Literature review and discussion.Results: Early mammary tissue development occurs prenatally. This process is hormone-independent and occurs similarly in males and females. Breast tissue is quiescent until puberty, at which time surging estrogen levels in cisgender girls mediate breast development and growth. Adult breast tissue composition further evolves in cisgender women during pregnancy, lactation, and menopause, revealing the ever-changing interplay between breast structure and hormonal environment.Conclusion: Breast growth is a significant physical endpoint in the hormonal treatment of transgender women. Transgender hormone regimens, which typically pair an estrogen with an anti-androgen, can help achieve this goal.     

Metabolic Effects Of Hormone Therapy In Transgender Patients

Objective: Transgender patients may seek hormone therapy to induce physical changes to simulate their expressed or experienced gender. However, many providers are uncomfortable prescribing transgender hormones due to fears over safety. The goal of this study was to determine if transgender hormone therapy with estrogen and spironolactone for male-to-female (MtF) patients or with testosterone for female-to-male (FtM) patients had adverse anthropomorphic or metabolic effects.Methods: This retrospective chart review study analyzed changes over time for 33 MtF and 19 FtM endocrine clinic patients at an academic endocrine practice with follow-up for up to 18 months after hormone initiation.Results: Compared to baseline labs obtained prior to the initiation of hormone therapy, significant changes for the MtF cohort included an increase in high-density lipoprotein (HDL) and decrease in creatinine; however, triglycerides did not show a statistically significant change. In the FtM cohort, there were significant increases in body mass index, creatinine, hemoglobin, and hematocrit. Although statistically significant, these changes were minimal for both cohorts.Conclusion: In our practice, hormone therapy was found to be safe in this retrospective study.Abbreviations:BMI = body mass indexFtM = female-to-maleHDL = high-density lipoproteinLDL = low-density lipoproteinMtF = male-to-female     

EXOGENOUS TESTOSTERONE DOES NOT INDUCE OR EXACERBATE THE METABOLIC FEATURES ASSOCIATED WITH PCOS AMONG TRANSGENDER MEN

Objective: Polycystic ovary syndrome (PCOS) is a complex condition which can include menstrual irregularity, metabolic derangement, and increased androgen levels. The mechanism of PCOS is unknown. Some suggest that excess production of androgens by the ovaries may cause or exacerbate the metabolic findings. The purpose of this study was to assess the role of increased testosterone on metabolic parameters for individuals presumed to be chromosomally female by examination of these parameters in hormone-treated transgender men.Methods: In 2015 and 2016, we asked all transgender men who visited the Endocrinology Clinic at Boston Medical Center treated with testosterone for consent for a retrospective anonymous chart review. Of the 36 men, 34 agreed (94%). Serum metabolic factors and body mass index (BMI) levels for each patient were graphed over time, from initiation of therapy through 6 years of treatment. Bivariate analyses were conducted to analyze the impact of added testosterone.Results: Regressions measuring the impact of testosterone demonstrated no significant changes in levels of glycated hemoglobin (HbA1c), triglycerides, or low-density-lipoprotein cholesterol. There was a statistically significant decrease in BMI with increasing testosterone. There was also a statistically significant decrease in high-density lipoprotein levels upon initiation of testosterone therapy.Conclusion: Testosterone therapy in transgender men across a wide range of doses and over many years did not result in the dyslipidemia or abnormalities in HbA1c seen with PCOS. Instead, treatment of transgender men with testosterone resulted only in a shift of metabolic biomarkers toward the average physiologic male body.Abbreviations: BMI = body mass index; HbA1c = glycated hemoglobin; HDL = high-density lipoprotein; LDL = low-density lipoprotein; PCOS = polycystic ovary syndrome     

Evidence-Based Curricular Content Improves Student Knowledge and Changes Attitudes towards Transgender Medicine

Objective: Previous studies have demonstrated that the addition of transgender medicine content to a medical school curriculum increased students' comfort and willingness to treat transgender patients. We aimed to demonstrate that (1) evidence-based curricular content would improve knowledge of and change attitudes towards transgender medicine, and (2) students would consider cross-sex hormone therapy a legitimate treatment option for transgender patients.Methods: Curricular content with a focus on the biologic evidence for the durability of gender identity was added to the first-year medical program at Boston University School of Medicine. Immediately before and after exposure to the content, students were presented with an assessment of their knowledge of the etiology of gender identity.Results: Immediately following exposure to the content, a significant number of students changed their answer regarding the etiology of gender identity so that the number of correct responses increased from 63% (n = 56) to 93% (n = 121) (P<.001). For transgender treatment, the number of correct responses increased from 20% (n = 56) before exposure to the content to 50% (n = 121) following exposure (P<.001).Conclusion: The addition of transgender medicine content to a medical school curriculum with a focus on the biologic evidence for a durable gender identity is an effective means of educating students about the etiology of gender identity and the appropriateness of cross-sex hormone therapy as a treatment for transgender patients.     

Observed Deficiencies in Medical Student Knowledge of Transgender and Intersex Health

Objective: Lesbian, gay, bisexual, transgender, and intersex (LGBTI) patients face many well-documented disparities in care which among transgender and intersex people can often be traced to providers' lack of knowledge.Methods: We administered surveys to examine the self-assessed knowledge and attitudes of all medical students at Boston University regarding different LGBTI subpopulations. Survey questions were based on a Likert scale from 1 to 5; analysis was conducted with Wilcoxon rank sum tests.Results: Overall there was a response rate of 24%, with the number of responses varying by class. Three of the 4 surveyed classes reported lower knowledge about transgender health than LGB health. Every class reported significantly lower knowledge of intersex health in comparison to LGB. Comfort with transgender or with intersex patients was lower than with LGB patients for all surveyed classes. Students across all self-identified groups (LGBTI, ally, not an ally) reported significantly lower average responses for knowledge and comfort regarding transgender or intersex health in comparison to that of LGB. Students in their preclinical years reported lower levels of knowledge in comparison with students in their clinical years. Students who identified as LGBTI reported significantly higher knowledge and comfort with only LGB and transgender health when compared with students who didn't identify as LGBTI. Respondents more frequently requested additional learning opportunities in transgender and intersex health than in LGB health.Conclusion: Self-reported knowledge of transgender and intersex health lags behind knowledge of LGB health, though these deficits appear partially responsive to targeted educational intervention.Abbreviations: BUSM = Boston University School of Medicine LGB = lesbian, gay, and bisexual LGBT = lesbian, gay, bisexual, and transgender LGBTI = lesbian, gay, bisexual, transgender, and intersex M1 = first-year medical student class M2 = second-year medical student class M3 = third-year medical student class M4 = fourth-year medical student class     

Endocrinology Fellows' Perception of Their Confidence and Skill Level in Providing Transgender Healthcare

Objective: Both educational content and hours devoted to transgender health training of endocrinology fellows are suboptimal. The objective of this study was to assess the perspectives of endocrinology fellows on their training in transgender health.Methods: We evaluated the state of comfort and knowledge of transgender healthcare among endocrinology fellows attending Endocrine University. Surveys were administered to fellows before and after their participation in a case-based session on transgender health.Results: The majority of fellows felt that training in transgender health is important (95.9%, 189/197); however, only 58.9% reported inclusion of dedicated transgender content in their training programs. Fellows who had received transgender healthcare education, and those who had seen more transgender patients in their training, were more likely to be confident in treating patients with hormone therapy (P<.001 and P<.0001, respectively). Following the case-based session, 62.4 % of fellows reported that they would change their practice, 72.8% felt that their comfort level with transgender care had improved, and 91% felt that transgender content such as that provided in the educational session should be mandatory in endocrinology training programs. Methods most desired by fellows to improve their education included lectures from visiting professors (70.3%), participation in elective rotations (62.1%), online training modules (57.9%), and attendance at meetings with transgender topics (57.4%).Conclusion: Transgender health education of U.S. endocrinology fellows is suboptimal. Participation in a case-based session significantly increased the comfort level of endocrinology fellows in key areas of transgender health.Abbreviation: ACGME = Accreditation Council for Graduate Medical Education     

Thyroid Function and Metabolic Syndrome: A Cross-Sectional Study in Obese and Overweight Patients

Objective: Metabolic syndrome (MetS) is associated with increased risks of developing cardiovascular disease and type 2 diabetes. Thyroid dysfunction is also a known cardiovascular risk factor. In obese patients, serum thyroid-stimulating hormone (TSH) levels tend to be higher than in lean controls. The objective of this study was to assess potential associations between serum TSH levels and MetS as well as individual components of MetS.Methods: This was a cross-sectional observational study of obese and overweight patients seen for initial evaluation at the Boston Medical Center weight-management clinic between February 1, 2013 and February 1, 2014. Demographic, anthropometric, and laboratory data including serum TSH, insulin, glucose, hemoglobin A_1c, and lipid levels were obtained from electronic medical records. Associations between serum TSH levels and presence of MetS and its components were assessed.Results: A total of 3,447 patients, 75.6% female and 38% African American, without known thyroid dysfunction, were included. Mean ± SD age was 46.74 ± 15.11 years, and mean ± SD body mass index was 36.06 ± 9.89 kg/m². Among 1,005 patients without missing data, the prevalence of MetS was 71.84%. In patients with MetS, the median serum TSH was 1.41 μIU/mL, compared with 1.36 μIU/mL in patients without MetS (P = .45). In multivariate models, there was no significant association between serum TSH levels and the presence of MetS, adjusting for age, sex, race, education, socioeconomic status, and smoking. There were also no significant associations between serum TSH and individual components of the MetS.Conclusion: Serum TSH level does not appear to be a potentially modifiable risk factor for MetS in obese and overweight individuals.Abbreviations: BMI = body mass index FT₄ = free thyroxine HDL-C = high-density-lipoprotein cholesterol HbA_1c = hemoglobin A_1c MetS = metabolic syndrome SE = standard error TSH = thyroid-stimulating hormone     

Children and Adolescents with Gender Dysphoria in Israel: Increasing Referral and Fertility Preservation Rates

Objective: To describe patient characteristics at presentation, management, and fertility preservation rates among a cohort of Israeli children and adolescents with gender dysphoria (GD).Methods: We performed a retrospective chart review of 106 consecutive children and adolescents with GD (<18 years) referred to and followed at the multidisciplinary Israeli Pediatric Gender Dysphoria Clinic from March 2013 through December 2018.Results: Of the 106 patients, 10 were prepubertal (9 prepubertal transgender females), and 96 were pubertal (38 pubertal transgender females). The GD population increased 11-fold since the establishment of our clinic in 2013. The subject's median age at referral was 15.5 years (range, 4.6 to 18 years). At the time of referral, 91 (95%) of the pubertal group had completed sexual maturation in their assigned gender at birth. Thirteen (13.5%) patients had attempted suicide, and 11 (11.5%) reported having had suicidal thoughts. Fourteen (45%) pubertal transgender females and 3 (6.5%) pubertal transgender males completed fertility preservation. Gonadotropin-releasing hormone analog treatment was prescribed in 77 (80%) patients at a mean age of 15.9 ± 1.6 years. Gender-affirming hormones were prescribed in 61 (64%) patients at a mean age of 16.5 ± 1.3 years. No severe side effects were recorded. Two (2%) of the pubertal group expressed regret about medical treatment.Conclusion: Children and adolescents with GD are presenting for medical attention at increasing rates. Israeli adolescents with GD have high fertility preservation rates, perhaps attributable to cultural perspectives. Taking advantage of the option to preserve fertility can be achieved when proper counseling is both available and promoted by medical personnel.Abbreviations: GAH = gender-affirming hormone; GD = gender dysphoria; GnRHa = gonadotropin-releasing hormone analog; MHP = mental health professional     

Hypoglycemia Rates After Restriction of High-Dose Glargine in Hospitalized Patients

Objective: Hypoglycemia remains one of the main challenges of insulin therapy. To reduce insulin-related hypoglycemia at our institution, we restricted inpatient ordering of high glargine doses (≥0.5 U/kg/day) to endocrine staff in May 2013. This retrospective cohort study assesses its effect on hypoglycemia and glycemic control within 48 hours of admission (ADM).Methods: We identified 692 adult patients hospitalized at Boston Medical Center who received glargine upon ADM from November 1, 2012 through April 30, 2013 as the pre-intervention group, and 651 adult patients admitted between November 1, 2013 and April 30, 2014 as the postintervention group. Demographics, medical history, home insulin regimen, concurrent oral diabetes medications or glucocorticoid administration, ADM serum creatinine, all blood glucose levels (BG) ≤48 hours of ADM, and hemoglobin A1c values ≤3 months were assessed. Hypoglycemia was defined as BG ≤70 mg/dL, and hyperglycemia as BG ≥200 mg/dL. Multivariable regression models assessed potential associations between covariates and incidence of hypoglycemia and average BG ≤48 hours of ADM.Results: Demographics were similar between groups. Significantly less patients received high-dose glargine in the post-intervention group (5.2% vs. 0.3%, P<.001). Incidences of hypoglycemia were significantly lower in the postintervention group (20.9% vs. 17.8%, P<.001 per ADM; 3.4% vs. 2.3%, P = .001 per BG measurements [BGM]). Mean BG levels ≤48 hours of ADM and incidence of hyperglycemia were not significantly different. The adjusted incident rate ratio of hypoglycemia was 0.63 per ADM and 0.74 per BGM in the postintervention group compared to the pre-intervention group (P = .001 and P = .063, respectively).Conclusion: We found that implementation of a restriction on high doses of glargine resulted in lower rates of hypoglycemia without worsening glycemic control.Abbreviations:ADM = admissionBG = blood glucoseBGM = blood glucose measurementsBMC = Boston Medical CenterBMI = body mass indexEMR = electronic medical recordHgbA1c = hemoglobin A1cIRR = incidence rate ratioNPH = neutral protamine HagedornTDD = total daily doseT2D = type 2 diabetes     

Short-Term Decline in Prolactin Concentrations Can Predict Future Prolactin Normalization,Tumor Shrinkage,and Time to Remission in Men with Macroprolactinomas

Objective: To identify early follow-up measures that will predict the dynamics of prolactin (PRL) decrease and adenoma shrinkage in men harboring macroprolactinomas.Methods: A single-center historical prospective study including a consecutive group of 71 men with pituitary macroadenomas (≥10 mm) and hyperprolactinemia (PRL >7 times the upper limit of normal &lsqb;ULN]) treated medically with cabergoline. Comparisons of PRL normalization rates were performed according to PRL levels achieved at 6 months, maximal adenoma shrinkage during follow-up, and other patient characteristics. Correlations were analyzed to identify characteristics of PRL suppression dynamics.Results: PRL levels after 6 months of treatment correlated positively with current PRL levels (r = 0.74; P<.001), with time to PRL normalization (r = 0.75; P<.001), and with adenoma diameter following treatment (r = 0.38; P = .01). Adenoma shrinkage depicted by first magnetic resonance imaging on treatment correlated with maximal adenoma shrinkage during follow-up (r = 0.56; P = .006). Five patients had nadir PRL levels ≥3 times the ULN (51 ng/mL) and showed slower response to cabergoline treatment, with consistently higher PRL levels compared with responding patients throughout follow-up (mean 6-month PRL levels, 519 ± 403 ng/mL versus 59 ± 118 ng/mL; P<.001).Conclusion: Six-month PRL level might serve as a surrogate marker for PRL normalization and adenoma shrinkage dynamics among men harboring macroprolactinomas.Abbreviations: CAB = cabergoline MRI = magnetic resonance imaging PRL = prolactin RMC = Rabin Medical Centre ULN = upper limit of normal     

Pituitary Imaging By Mri and its Correlation with Biochemical Parameters in the Evaluation of Men with Hypogonadotropic Hypogonadism

Objective: A significant ambiguity still remains about which patient deserves a magnetic resonance imaging (MRI) scan of the pituitary during evaluation of hypogonadotropic hypogonadism (HH) in men.Methods: Retrospective case series of 175 men with HH referred over 6 years.Results: A total of 49.7% of men had total testosterone (TT) levels lower than the Endocrine Society threshold of 5.2 nmol/L. One-hundred forty-two patients (81.2%) had normal appearance of pituitary MRI, whereas others had different spectrum of abnormalities (empty sella &lsqb;n = 16], macroadenoma &lsqb;n = 8], microadenoma &lsqb;n = 8], and pituitary cyst &lsqb;n = 1]). In men with TT in the lowest quartile, MRI pituitary findings were not significantly different from men in the remaining quartiles (P = .50). Patients with raised prolactin had higher number of abnormal MRI findings (38.9% vs. 13.7%; P = .0014) and adenomatous lesions (macro and micro) (27.8% vs. 4.3%; P = .01) in comparison to men with normal prolactin. The prolactin levels (median &lsqb;interquartile range]) were highest in men with macroadenomas in both groups (9,950 &lsqb;915]; P = .007 and 300 &lsqb;68.0] mU/L; P = .02, respectively), with concomitant lower levels of other pituitary hormones. Multivariate logistic regression showed an association of abnormal pituitary MRI with insulin-like growth factor 1 (IGF-1) standard deviation score (SDS) (odds ratio &lsqb;OR], 1.78 &lsqb;95% confidence interval (CI), 1.15 to 2.77]; P = .009) and prolactin (OR, 1.00 &lsqb;95% CI, 1.00 to 1.03]; P = .01).Conclusion: MRI of the pituitary is not warranted in all patients with HH, as the yield of identifiable abnormalities is quite low. Anatomic lesions are likely to be present only when low levels of TT (<5.2 nmol/L) are found concomitantly with high levels of prolactin and/or low IGF-1 SDS.Abbreviations: CI = confidence interval; FT4 = free thyroxine; GH = growth hormone; HH = hypogonadotropic hypogonadism; IGF-1 = insulin-like growth factor; LH = luteinizing hormone; MRI = magnetic resonance imaging; OR = odds ratio; SDS = standard deviation score; TSH = thyroid-stimulating hormone; TT = total testosterone     

Study Of The Prevalence Of Autoimmune Thyroid Disease In Women With Breast Cancer

Objective: The aim of this study was to analyze the prevalence of thyroid disorders in patients with a positive biopsy for breast cancer prior to specific antitumor treatment.Methods: The frequency and pattern of thyroid disorders were evaluated in 112 patients with breast cancer (G1) and 125 control patients (G2) by analyzing serum thyroid-stimulating hormone (TSH), anti–thyroid peroxidase antibodies, and anti-thyroglobulin antibodies. In addition, the expression of estrogen receptors, progesterone receptors, and human epidermal growth factor receptor 2 (HER2) was assessed in the breast biopsies by immunohistochemistry.Results: The frequency of thyroid disorders, such as changes in TSH levels and/or the presence of thyroid antibodies, was not different between the 2 groups examined (30.4% in G1 versus 28.0% in G2) (P = .69). However, a family history of thyroid disease was more frequent in patients with breast cancer (50.5% in G1 versus 28.2% in G2) (P = .001). Regarding the clinical stage of breast cancer, there was no difference between women with autoimmune thyroiditis and those without thyroid dysfunction (P = .316). Similarly, there were no differences in hormone receptor (estrogen or progesterone) and HER2 expression between patients who tested positive and those who tested negative for anti-thyroid antibodies (P = .052 and P = .549, respectively).Conclusion: The data obtained in this study did not reveal a higher frequency of autoimmune thyroid disease in patients with breast cancer compared to controls. A family history of thyroid disease was more common in those with breast cancer.Abbreviations:anti-Tg = anti-thyroglobulinanti-TPO = anti–thyroid peroxidaseBIRADS = Breast Imaging-Reporting and Data SystemER = estrogen receptorFT₄ = free thyroxineG1 = study groupG2 = final control groupHER2 = human epidermal growth factor receptor 2PR = progesterone receptorTSH = thyroid-stimulating hormone     

Potassium Concentrations in Transgender Women Using Spironolactone: A Retrospective Chart Review

ObjectiveTo assess the incidence of hyperkalemia in transgender women using spironolactone.MethodsThis was a retrospective chart review of transgender women who received gender-affirming hormone therapy that included spironolactone between January 2000 and September 2018. Forty-four participants who had paired potassium concentrations documented and were on spironolactone were included and analyzed. Study outcomes included the incidence of hyperkalemia (serum potassium concentrations > 5.0 mmol/L), the relationship between the duration of treatment and degree of hyperkalemia, and difference between serum potassium concentrations at the beginning of spironolactone treatment versus last serum potassium concentrations.ResultsThe median age of the participants was 36.5 years. The cohort was predominantly non-Hispanic White (32/44). No serum potassium concentration was >5.5 mmol/L, and all participants had serum creatinine level of <2 mg/dL. Median duration of treatment was 25 months (range 2-92 months) and 140 potassium measurements were available. The mean potassium concentration (3.87 mmol/L) before the initiation of spironolactone was lower than the mean potassium concentration (4.03 mmol/L) while on spironolactone (mean difference, 0.16 mmol/L, P = .013). The regression β, that is, the average change in potassium concentration per 1 additional month of treatment duration, was ?.001 (95% CI [?.004, .001]; P = .255) signifying no relation between treatment duration and spironolactone use.ConclusionNo participant had laboratory evidence of significant hyperkalemia (K > 5.5 mmol/L) after initiation of spironolactone. Frequent measurement of potassium concentrations might be unnecessary in transgender women taking spironolactone in patients with serum creatinine levels of <2 mg/dL.     

The Effect of Raloxifene on Serum Prolactin Level in Patients with Prolactinoma

Objective: To evaluate the effect of raloxifene on prolactin (PRL) levels in addition to dopamine agonist (DA) therapy in patients with prolactinoma.Methods: We conducted a retrospective chart review of 14 patients with prolactinoma on stable dose of DA for 6 months who received raloxifene 60 mg daily, as PRL could not be normalized despite being on fairly high doses of DA. Patients were informed that raloxifene is not approved by the Food and Drug Administration for prolactinoma treatment. PRL level was measured at 1 to 6 months after starting raloxifene and at 1 to 3 months following its discontinuation. Raloxifene was stopped in 8 out of 14 patients after 2 (1 to 6) months of treatment as the absolute change in PRL level was felt to be small.Results: The median age and female/male sex ratios were 50 years (range 18 to 63 years), 6/8 respectively. The baseline DA dose was 3 mg/week (0.5 to 7 mg/week) for cabergoline and 15 mg/day for bromocriptine. Ten patients had an absolute and percentage decrease in PRL of 8.3 ng/mL (1.5 to 54.2 ng/mL) and 25.9% (8 to 55%) from baseline, respectively, after 1 to 6 months on raloxifene treatment. Among 10 patients with a decrease in PRL level, 2 (20%) achieved PRL normalization. Two patients had no change in PRL and two patients had an increase in PRL level by 22.8 ng/mL and 8.8 ng/mL (47% and 23.6%), respectively.Conclusion: Raloxifene was associated with a 25.9% (8 to 55%) decrease in PRL level in 10/14 (71%) patients with prolactinoma who were on stable doses of DA including 2 patients (14%) who achieved normoprolactinemia.Abbreviations: CV = coefficient of variation; DA = dopamine agonist; FSH = follicule-stimulating hormone; LH = luteinizing hormone; PRL = prolactin; PTTG = pituitary tumor transforming gene     

High Body Mass Index is A Significant Barrier to Gender-Confirmation Surgery for Transgender and Gender-Nonbinary Individuals

Objective: Transgender and gender-nonbinary individuals (TGNB) are disproportionately impacted by obesity. In addition to the associated health impact, obesity represents a significant barrier to accessing gender-confirmation surgery (GCS). The purpose of this study was to determine the prevalence of obesity among TGNB surgical candidates at an urban academic medical center and evaluate the efficacy of self-monitored weight management.Methods: The study was conducted at the Center for Transgender Medicine and Surgery at Mount Sinai in New York City. Data abstraction from a quality improvement database was completed for patients with a documented body mass index (BMI) and a GCS consult from October 2015 through February 2019. A total of 1,457 TGNB patients with a documented BMI and a GCS consult in the historical period of review were included in analysis. Data were abstracted to determine the prevalence of obesity among GCS candidates and evaluate the current default pre-operative self-monitored weight management protocol.Results: Of 1,457 TGNB patients, 382 (26%) were obese (BMI ≥30 kg/m²) at initial surgical consult. In addition, 369 (27%) were obese at a subsequent follow-up, suggesting no statistically significant change in the rate of obesity among evaluated TGNB despite self-monitored weight management (P = .5272).Conclusion: Obesity is a significant barrier to gender affirming surgery for transgender individuals. Self-monitored weight management is an unsuccessful strategy for improvement even among individuals who would be predicted to be motivated.Abbreviations: BMI = body mass index; CTMS = Center for Transgender Medicine and Surgery (at Mount Sinai); GCS = gender confirmation surgery; TGNB = transgender and gender-nonbinary     

Hyperthyroidism and Hyperprolactinemia: Is There any Association?

Objective: To compare the serum prolactin level in hyperthyroid and normal control females. Hyperthyroidism is a common disease. Although a direct association has been demonstrated between hypothyroidism and increased prolactin levels, this association has not been established for hyperthyroidism.Methods: Cross-sectional study in cases and control groups. Control subjects were chosen from those participating in the Kerman Coronary Artery Disease Risk Factors study. To select the cases, all women referred to the laboratories of Kerman with a thyroid-stimulating hormone (TSH) level ≤0.5 mIU/L who met the inclusion criteria were entered in the study. A total of 231 women aged 15 to 50 years were enrolled. The case group included 71 hyperthyroid women, and the control group included 160 women with normal thyroid function matched by age.Results: The mean (SD) serum level of prolactin was 16.56 (0.97) ng/mL (95% confidence interval [CI], 15.41 ng/mL to 15.71 ng/mL) in the controls and 23.07 (1.49) ng/mL (95% CI, 22.7 ng/mL to 23.4 ng/mL) in the case subjects. Hyperprolactinemia was more common in the hyperthyroid group (16.5 [0.97] ng/mL versus 23.07 [1.49] ng/mL; P<.001). The prolactin level decreased with age. Hyperthyroidism and estradiol increased the prolactin level. After adjusting for age and estradiol, hyperthyroidism increased the serum prolactin level (P<.001).Conclusion: The results of this study revealed that hyperprolactinemia is more frequent in hyperthyroid females. Serum prolactin level can be increased in hyperthyroidism.Abbreviations:PRL = prolactinT4 = thyroxineTRH = thyrotropin-releasing hormoneTSH = thyroid-stimulating hormone     

UPDATE ON THE CLINICOPATHOLOGY OF PITUITARY ADENOMAS

Objective: Pituitary adenomas are the third most common central nervous system tumors and arise from the anterior pituitary within the pituitary fossa.Methods: Literature review and discussion.Results: The signs and symptoms of patients with pituitary adenomas vary from ‘mass effects’ caused by a large adenoma to features secondary to excess pituitary hormones produced by the functioning pituitary adenoma. Detailed histopathologic assessment, based on novel classifications and the latest World Health Organization guidelines, helps to categorize pituitary adenomas into different subtypes and identify features that, in some cases, help to predict their behavior. Most of the pituitary tumors occur sporadically without known genetic predisposition, but in a significant minority of cases, somatic mutations can be identified in the GNAS and USP8 genes. A small proportion of the cases have germline genetic defects or embryonic mutations leading to mosaicism. Genes with germ-line mutations predisposing to pituitary adenomas include AIP, GPR101, MEN1, CDKN1B, PRKAR1A, PRKAR2A, DICER1, NF1, and SDHx, whereas more recently, CABLES1 has also been implicated.Conclusion: Understanding the pathogenesis of pituitary adenomas will allow clinicians to correlate the pathologic and genetic features with clinical data, helping decisions on the best management of these tumors.Abbreviations: ACTH = adrenocorticotropic hormone; AIP = aryl hydrocarbon receptor-interacting protein; αSU = alpha-subunit; EGFR = epithelial growth factor receptor; ER = estrogen receptor; FSH = follicle-stimulating hormone; GH = growth hormone; GHRH = growth hormone–releasing hormone; IGF-1 = insulin-like growth factor 1; LH = luteinizing hormone; MEN1 = multiple endocrine neoplasia 1; MRI = magnetic resonance imaging; NFPA = nonfunctioning pituitary adenoma; PRL = prolactin; TSH = thyroid-stimulating hormone; USP8 = ubiquitin-specific peptidase 8; WHO = World Health Organization