The Classic and Nonclassic Concenital Adrenal Hyperplasias

Objective: The American Association of Clinical Endocrinologists Adrenal Scientific Committee has developed a series of articles to update members on the genetics of adrenal diseases.Methods: Case presentation, discussion of literature, table, and bullet point conclusions.Results: The congenital adrenal hyperplasia (CAH) syndromes are autosomal recessive defects in cortisol biosynthesis. The phenotype of each CAH patient depends on the defective enzyme and the severity of the defect. Clinical manifestations derive from both failure to synthesize hormones distal to the enzymatic block, as well as consequences from cortisol precursor accumulation proximal to the block, often with diversion to other biologically active steroids. The most common form of CAH is 21-hydroxylase deficiency, which occurs in the classic form in 1 in 16,000 newborns and in a milder or nonclassic form in at least 1 in 1,000 people.Conclusion: This article reviews the various forms of CAH and pitfalls in the diagnosis and treatment of these conditions.Abbreviations: 11OHD = 11-hydroxylase deficiency 17OHD = 17-hydroxylase deficiency 17OHP = 17-hydroxyprogesterone 21OHD = 21-hydroxylase deficiency 3βHSD = 3β-hydroxysteroid dehydrogenase CAH = congenital adrenal hyperplasia CST = cosyntropin stimulation test CYP17A1 = cytochrome P450 17A1 (steroid 17-hydroxylase/17,20-lyase) DHEAS = dehydroepiandrosterone sulfate DSD = disorder of sex development LCAH = lipoid congenital adrenal hyperplasia NBS = newborn screening NCAH = nonclassic CAH PCOS = polycystic ovary syndrome PORD = P450-oxidoreductase deficiency     

Increasing Prevalence Of Addison Disease: Results From A Nationwide Study

Objective: Primary adrenal insufficiency is a life-threatening endocrine disease unless properly treated. However, few studies on the prevalence, concomitances of the disease, and prescribing of drugs have been published. The goal of the study was to establish the prevalence of primary adrenal insufficiency in Iceland and additionally, to study the most common concomitant diseases in patients with primary adrenal insufficiency, as well as the mode of glucocorticoid replacement therapies.Methods: To achieve this, the medical records of all patients in Iceland who had received the International Classification of Diseases and Related Health Problems, 10th Revision, diagnosis code E27, were evaluated for true primary adrenal insufficiency. Additionally, these records were evaluated for concomitant diseases, as well as the mode of glucocorticoid replacement therapy. The study covered the whole population of Iceland over 18 years of age. It was thus a nationwide study. The records were retrieved from large hospitals and clinics and every practicing specialist in endocrinology.Results: Primary adrenal insufficiency was found in 53 individuals, 26 women and 27 men, yielding a prevalence of 22.1 per 100,000 population. Hypothyroidism was by far the most common concomitant disease. Most patients had their glucocorticoid deficiency replaced with shortacting glucocorticoids.Conclusion: The prevalence of primary adrenal insufficiency in Iceland is higher than in earlier reports, with comorbidities being in line with recent studies. Treatment is according to the latest protocols.Abbreviations:CAH = congenital adrenal hyperplasiaCVD = cardiovascular diseaseDM = diabetes mellitusGC = glucocorticoidLSH = Landspitali National University HospitalPAI = primary adrenal insufficiencyPAS = polyendocrine autoimmune syndrome     

Genetic Basis of Bilateral Macronodular Hyperplasia

Objective: To review the genetic basis of bilateral macronodular hyperplasia (BMAH).Methods: Case presentation, review of literature, table, and bullet point conclusions.Results: BMAH, also known as adrenocorticotropic hormone (ACTH)-independent macronodular hyperplasia (AIMH), can cause Cushing syndrome or mild hypercortisolism. Recent studies have demonstrated that hyperplastic tissue reproduces ectopic ACTH, implying that BMAH is the more proper term, as the syndrome is not ACTH-independent. BMAH was thought to be sporadic, but recent data have shown that there is likely a genetic component in the majority of cases. Mutations in ARMC5, a putative suppressor gene, have been found in many familial cases of BMAH and are thought to be responsible for the disorder. As these nodules inefficiently produce cortisol, large nodules are required to produce a clinical syndrome. ARMC5 likely requires a second somatic mutation to become clinically apparent. Clinical manifestations are not generally noted until the fifth to sixth decades of life.Conclusion: BMAH is an underrecognized genetic condition that can lead to Cushing syndrome and should be screened for in patients and susceptible family members.Abbreviations: ACTH = adrenocorticotropic hormone AIMAH = ACTH-independent macronodular adrenal hyperplasia ARMC5 = armadillo-repeat containing 5 BMAH = bilateral macronodular adrenal hyperplasia CAH = congenital adrenal hyperplasia CT = computed tomography MEN1 = multiple endocrine neoplasia 1 UFC = urinary free cortisol     

Molecular pathogenesis of lipoid adrenal hyperplasia and adrenal hypoplasia congenita

Congenital lipoid adrenal hyperplasia (lipoid CAH) is the most severe form of CAH in which the synthesis of all gonadal and adrenal cortical steroids is markedly impaired. Lipoid CAH may be caused by the defect in either the steroidogenic acute regulatory (StAR) protein or the P450scc. More than 34 different mutations in StAR gene have been identified. Clinically, most of the patients manifest adrenal insufficiency from 1 day to 2 months of age, but some patient show delayed onset of adrenal insufficiency. Affected 46, XY subjects do not show pubertal development, whereas affected 46, XX subjects undergo spontaneous feminization, breast development and cyclical vaginal bleeding at the usual age of puberty.

X-linked adrenal hypoplasia congenital (AHC) is a rare congenital adrenal disorder characterized by severe adrenal insufficiency and hypogonadotropic hypogonadism. More than 80 different several intragenic mutations of DAX-1 have been identified. The failure of pubertal development may be caused by either abnormal hypothalamic or pituitary regulation of gonadotropin secretion. In addition, although the testicular steroidogenesis is largely intact, the functional maturity of Sertoli cells and also spermatogenesis are impaired. The type of mutation does not predict clinical phenotype. Thus, unified mechanism how DAX-1 gene defect gives rise to adrenal insufficiency, hypothalamic/pituitary hypogonadism and impaired spermatogenesis remains established.     

Congenital Adrenal Hyperplasia Due to 21-Hydroxylase Deficiency Presenting as Adrenal Incidentaloma: A Systematic Review and Meta-Analysis

Objective: Adrenal incidentalomas (AIs) may be due to congenital adrenal hyperplasia (CAH) due to homozygous CYP21A2 mutations, or perhaps from heterozygous carrier status. It is unclear if genetic or biochemical testing of CYP21A2 status in AI is justified, despite its potential for avoiding adrenal crises in those referred for adrenalectomy.Methods: We systematically searched PubMed/MEDLINE for articles published up to October 19, 2015 containing all terms associated with adrenal tumors and CAH. Meta-analyses were used to estimate the CAH or carrier prevalence in AI and assess clinical factors that may guide testing.Results: Thirty-six publications were included. Of AI patients biochemically screened for CAH, 58/990 (5.9%) were diagnosed with CAH. Genetic screening of all AIs revealed only 2/252 (0.8%) with clear CAH. The carrier prevalence was 10.2% (36/352). The rate of 0.8% (8/1,000) genetically confirmed CAH is higher than the 1/15,000 affected by classic CAH or 1/1,000 by nonclassic CAH in the Caucasian population. The rate of heterozygous CYP21A2 mutation frequency is similar to those in reported in population studies. Levels of both basal and stimulated 17-hydroxyprogesterone positively correlated with AI diameter. Although bilateral incidentalomata were frequent in CAH, their presence did not predict CYP21A2 status.Conclusion: The presence of an AI does not increase the probability of detection of CAH or CYP21A2 carrier status to the extent routine genetic testing is justified. Screening with 17-hydroxyprogesterone levels appears to lack specificity in the setting of an AI. CYP21A2 mutation analysis is probably the only reliable method for CAH diagnosis in AIs.Abbreviations:ACC = adrenocortical carcinomaACTH = adrenocorticotropic hormoneAI = adrenal incidentalomaCAH = congenital adrenal hyperplasiaNCAH = nonclassic congenital adrenal hyperplasia17OHP = 17-hydroxyprogesteroneSV = simple virilizing     

Bilateral Ovary Adrenal Rest Tumor in a Congenital Adrenal Hyperplasia Following Adrenalectomy

Objective:In contrast to the high incidence of testicular adrenal rest tumors in adult male patients with congenital adrenal hyperplasia (CAH), ovarian adrenal rest tumors (OARTs) in female CAH patients are rare. In this case report, we describe a case of bilateral OART in a female patient with CAH due to 21-hydroxylase deficiency.Methods:We present a detailed case report with the clinical, imaging, and laboratory findings of the patient. The pertinent literature is also reviewed.Results:A 17-year-old patient was known to have CAH due to 21-hydroxylase deficiency. Since the second month of her gestational age, her mother was treated with cortisone-replacement therapy. The patient was treated with hydrocortisone and fludrocortisone since the neonatal period. Her pertinent history included a bilateral adrenalectomy at the age of 13 years in 2006, and for 3 years she led a normal puberty life with no complaint with hormonal replacement therapy. Nevertheless, in 2009, she developed a virilizing syndrome. Subsequently, she underwent surgery in December 2009 for right adnexectomy. However, the regression of the masculinizing mass was not complete and worsened several months after the surgery. A new pelvic magnetic resonance image showed the activation of a contralateral ovarian mass, necessitating a left adnexectomy in August 2010.Conclusion:This case demonstrates some interesting features of OART that pose challenges to its management. If an OART is detected early enough and glucocorticoid therapy is received, it is possible that the OART will decrease in size following suppression of adrenocorticotropic hormone levels. (Endocr Pract. 2014;20:e69-e74)     

Energy Expenditure in 21-Hydroxylase Congenital Adrenal Hyperplasia Patients and Comparison with Predictive Equations

Objective: To characterize resting energy expenditure (REE) in patients with classic 21-hydroxylase congenital adrenal hyperplasia (21-OH CAH) using indirect calorimetry and compare it to the most commonly used REE predictive equations.Methods: This case-control study comprised 29 post-pubertal 21-OH CAH patients regularly followed at the University of Campinas. Elevated serum 17-hydroxyprogesterone and CYP21 gene molecular analysis confirmed the diagnosis. A healthy control group paired by age, gender, and body mass index was examined. Dual-energy X-ray absorptiometry (DEXA) measured body compositions. A bioimpedance analyzer determined fat-free mass, and indirect calorimetry using a metabolic cart measured REE.Results: Unlike our initial hypothesis, REE was similar between the groups (18.7 ± 3.1 kcal/kg/day in CAH vs. 20.3 ± 3.5 kcal/kg/day in controls; P = .728). No predictive equations reached the stipulated accuracy criteria, thus lacking validity in REE assessment in adults with the characteristics of the group studied. DEXA analysis revealed higher body fat and diminished nonbone lean mass in 21-OH CAH. Anthropometric and bioelectrical impedance parameters were not significantly different.Conclusion: Classic 21-OH CAH is generally followed in reference centers, which may facilitate indirect calorimetry use for REE measurement. Alternatively, considering our REE findings in adult 21-OH CAH patients, nutrition management based on 25 kcal/body weight/day (measured REE × activity factor 1.2 to 1.3) may be reasonable for current body weight maintenance in these patients.Abbreviations: 17-OHP = 17-hydroxyprogesterone; 21-OH CAH = classic 21-hydroxylase deficiency congenital adrenal hyperplasia; BMI = body mass index; REE = resting energy expenditure; VO2 = volume of oxygen; VCO₂ = volume of carbon dioxide     

Prevalence and Characteristics of Adrenal Tumors and Myelolipomas in Congenital Adrenal Hyperplasia: A Systematic Review and Meta-Analysis

Objective: The prevalence of adrenal tumors in congenital adrenal hyperplasia (CAH) is uncertain. Our objective was to estimate the prevalence and characteristics of adrenal tumors and myelolipoma in CAH, and investigate clinical features of this population.Methods: We carried out systematic searches in Medline Ovid and Embase for articles published until January, 2020. Studies with confirmed CAH, biochemically and/or genetically, were included. The two authors independently extracted data from each study.Results: Six cohort studies were included in the prevalence calculation. In addition, 32 case reports on adrenal myelolipomas and CAH were included. The prevalence of adrenal tumors in CAH was 29.3%. When only studies with genetically verified cytochrome P450, Family 21, subfamily A, polypeptide 2 gene (CYP21A2) mutations were included the prevalence was 23.6%. The prevalence of myelolipoma in CAH was 7.4% (verified CYP21A2 mutations 8.6%). The proportion of myelolipoma in the adrenal tumors was 25.4% (genetically verified 36.6%). The median (range) age at tumor diagnosis was 36.0 (12 to 60) years and there were more tumors in males than in females (37.9% versus 22.1%; P<.05). In patients with myelolipomas, 93.5% had an undiagnosed or poorly managed CAH.Conclusion: Patients with CAH had a high prevalence of adrenal tumors, particularly myelolipomas. Those with myelolipomas had a high frequency of late-diagnosed or poorly controlled CAH. Adrenal imaging may be considered in patients with CAH, especially if abdominal pain is present.     

Characterization of novel StAR (steroidogenic acute regulatory protein) mutations causing non-classic lipoid adrenal hyperplasia

Context

Steroidogenic acute regulatory protein (StAR) is crucial for transport of cholesterol to mitochondria where biosynthesis of steroids is initiated. Loss of StAR function causes lipoid congenital adrenal hyperplasia (LCAH).

Objective

StAR gene mutations causing partial loss of function manifest atypical and may be mistaken as familial glucocorticoid deficiency. Only a few mutations have been reported.

Design

To report clinical, biochemical, genetic, protein structure and functional data on two novel StAR mutations, and to compare them with published literature.

Setting

Collaboration between the University Children''s Hospital Bern, Switzerland, and the CIBERER, Hospital Vall d''Hebron, Autonomous University, Barcelona, Spain.

Patients

Two subjects of a non-consanguineous Caucasian family were studied. The 46,XX phenotypic normal female was diagnosed with adrenal insufficiency at the age of 10 months, had normal pubertal development and still has no signs of hypergonodatropic hypogonadism at 32 years of age. Her 46,XY brother was born with normal male external genitalia and was diagnosed with adrenal insufficiency at 14 months. Puberty was normal and no signs of hypergonadotropic hypogonadism are present at 29 years of age.

Results

StAR gene analysis revealed two novel compound heterozygote mutations T44HfsX3 and G221S. T44HfsX3 is a loss-of-function StAR mutation. G221S retains partial activity (∼30%) and is therefore responsible for a milder, non-classic phenotype. G221S is located in the cholesterol binding pocket and seems to alter binding/release of cholesterol.

Conclusions

StAR mutations located in the cholesterol binding pocket (V187M, R188C, R192C, G221D/S) seem to cause non-classic lipoid CAH. Accuracy of genotype-phenotype prediction by in vitro testing may vary with the assays employed.     

Germline Deletion of Armc5 In Familial Primary Macronodular Adrenal Hyperplasia

Objective: Primary macronodular adrenal hyperplasia (PMAH) is considered a predominantly sporadic disease, but familial forms are well recognized. Genetic studies revealed germline mutations in the armadillo repeat containing 5 gene (ARMC5) in the majority of PMAH cases. Furthermore, somatic ARMC5 mutations, as different types of second-hit mutations and loss of heterozygosity have been reported in each adrenal nodule in PMAH. Here, we describe the involvement of ARMC5 alteration in a familial case of PMAH.Methods: In our study, we performed clinical and genetic evaluations in a mother and her son with familial PMAH. To search for mutations and deletion of ARMC5, we used Sanger sequencing and droplet digital polymerase chain reaction (ddPCR), respectively.Results: Both patients showed the same phenotype of subclinical Cushing syndrome, with mild excess of mineralocorticoids and vasopressin-responsive cortisol secretion. The ddPCR analysis demonstrated that both mother and son had germline deletions in exons 1 to 5 of the ARMC5 gene locus. Furthermore, Sanger sequencing of DNA from the right and left adrenal nodules as well as peripheral blood of the son revealed the presence of another germline, missense mutation in ARMC5 exon 3 (p.P347S).Conclusion: This is the first report demonstrating germline deletion of ARMC5 in familial PMAH. In addition to investigating mutations, germline and somatic deletions of ARMC5 could be examined by ddPCR, which permits rapid and accurate evaluation of the ARMC5 allelic status.Abbreviations: ACTH = adrenocorticotropic hormone ARMC5 = armadillo repeat containing 5 CT = computed tomography ddPCR = droplet digital polymerase chain reaction LOH = loss of heterozygosity PMAH = primary macronodular adrenal hyperplasia     

Glucocorticoid-Induced Adrenal Insufficiency: A Study of the Incidence in Hospital Patients and A Review of Peri-Operative Management

Objective: Glucocorticoid (GC) pharmacotherapy is an effective treatment for a range of diseases, but exposure can suppress the hypothalamic-pituitary-adrenal axis, leading to glucocorticoid-induced adrenal insufficiency (GC-AI) in some patients. However, the incidence of diagnosed GC-AI and the associated health burden, including the incidence of adrenal crises (ACs), are unknown. Although GC-AI treatment is based on well-established principles, there are no agreed protocols regarding the peri-operative management of exposed patients. The aims of this study were to assess the incidence of diagnosed GC-AI in hospital patients and review current approaches to peri-operative management of surgical patients with GC exposure.Methods: An analysis of hospital admission data concerning adult patients diagnosed with GC-AI and a review of published recommendations for peri-operative GC cover.Results: Between 2001 and 2013, admission with a diagnosis of GC-AI in New South Wales, Australia was rare (annual average of 22.5 admissions/year) and ACs were even more rare (n = 3). Almost two-thirds (64.4%, n = 188) of the patients with diagnosed GC-AI were aged between 50 and 79 years and 45.2% (n = 132) had a comorbid infection. The current approach to peri-operative management of patients with GC exposure appears to be influenced by both the absence of clear guidelines and historic practices. This results in the exposure of some patients to supraphysiologic doses of GCs during the peri-operative period.Conclusion: Hospital admission with a diagnosis of GC-AI (with or without an AC) is very rare. Clear guidelines on peri-operative GC cover are necessary to avoid overreplacement with supraphysiologic doses in susceptible patients.Abbreviations: AC = adrenal crisis; ACTH = adrenocorticotropic hormone; AI = adrenal insufficiency; CI = confidence interval; GC = glucocorticoid; GC-AI = glucocorticoid-induced adrenal insufficiency; HPA = hypothalamic-pituitary-adrenal; OR = odds ratio     

Clinical Outcomes in Adrenal Incidentaloma: Experience From one Center

Objective: To investigate the outcome in patients with adrenal incidentaloma (AI).Methods: A retrospective evaluation of 637 patients with AI referred to a tertiary center over 8 years. Radiologic and hormonal evaluations were performed at baseline. Follow-up imaging was carried out if necessary, and hormonal evaluation was performed at 24 months according to national guidelines.Results: The mean age was 62.7 ± 11.6 years, and the mean AI size was 25.3 ± 17.0 mm at presentation. Hormonal evaluation revealed that 85.4% of all tumors were nonfunctioning adenomas, 4.1% subclinical Cushing syndrome (SCS), 1.4% pheochromocytoma, 1.4% primary hyperaldosteronism, 0.8% Cushing syndrome, 0.6% adrenocortical carcinoma, 0.3% congenital adrenal hyperplasia, 2.2% metastasis to adrenals, and 3.8% other lesions of benign origin. Bilateral tumors were found in 11%, and compared to unilateral tumors, SCS was more prevalent. Only 2 cases were reclassified during follow-up, both as SCS, but neither had had a dexamethasone suppression test performed at initial work-up. In patients diagnosed with an adrenal metastasis, 92.9% were deceased within 2 years. Excluding those with malignant tumors, 12.9% of patients died during the study period of up to 11 years due to other causes than adrenal.Conclusion: Most AIs were benign, but a small fraction of tumors were functional and malignant. The prognosis of patients with adrenal metastasis was extremely poor, but otherwise, the mortality rate was similar to that for the general population. Follow-up of AIs <4 cm with an initial nonfunctional profile and benign radiologic appearance appears unwarranted, but screening for congenital adrenal hyperplasia should be considered.Abbreviations: 17OHP = 17-hydroxyprogesterone ACC = adrenal cortical carcinoma ACTH = adrenocorticotropic hormone AI = adrenal incidentaloma CAH = congenital adrenal hyperplasia CT = computed tomography CS = Cushing syndrome DST = dexamethasone suppression test HPA = hypothalamic-pituitary-adrenal axis MRI = magnetic resonance imaging SCS = subclinical Cushing syndrome T2DM = type 2 diabetes mellitus UFC = urinary free cortisol     

Current Knowledge and Practices of Heath Care Professionals on Opioid-Induced Adrenal Insufficiency

Objective: Opioid-induced adrenal insufficiency (OIAI) is reported in up to 29% of chronic opioid users through suppression of the hypothalamus-pituitary-adrenal axis. Unrecognized adrenal insufficiency leads to increased morbidity and potentially death; thus, healthcare provider (HCP) awareness of OIAI is crucial. The aim of the present study was to assess the knowledge and current practices of HCPs regarding OIAI and to identify factors associated with decreased awareness.Methods: We carried out a cross-sectional, anonymous survey of HCPs in internal medicine specialties that prescribe or care for patients taking chronic opioids.Results: Of 91 (30%) participants who completed the survey, 51 (56%) were men and 52 (57%) were in training. Most responders were general internal medicine providers (n = 33, 36%), followed by endocrinologists (n = 13, 14%) and various other specialties (n = 45, 49%). While 61 (67%) of respondents prescribed opioids, only 17 (19%) were comfortable in their knowledge of opioid side effects. Among nonendocrine providers, 53 (68%) identified adrenal insufficiency as a known opioid-induced endocrinopathy. Compared to other providers, endocrinologists were more likely to recognize opioid-related endocrinopathies (69% versus 24%, P = .01) and to identify the correct symptoms for OIAI (38% versus 9%, P <.001). One in four nonendocrine providers reported discomfort in managing glucocorticoid replacement therapy. The majority (60%) of providers indicated that online resources and continuing medical education lectures would improve knowledge of OIAI.Conclusion: Our study identified several deficiencies in HCP knowledge of opioid-induced endocrine effects, especially in nonendocrine providers. As many symptoms of OIAI overlap with those of underlying conditions, OIAI could be potentially missed, highlighting the need to further educate providers about opioid-induced endocrinopathies.Abbreviations: ACTH = adrenocorticotropic hormone; AI = adrenal insufficiency; CME = continuing medical education; HCP = healthcare professional; OIAI = opioid-induced adrenal insufficiency     

X-Linked Adrenal Hypoplasia Congenita: A Case Report and Ethical Dilemma

ObjectiveOur objective is to present the first case report of X-linked adrenal hypoplasia congenita in a child conceived by a donated egg and which also presented atypically, with initial mineralocorticoid deficiency.MethodsCase report with literature review.ResultsA late preterm fraternal twin male, conceived by in vitro fertilization of donated eggs, presented shortly after birth with feeding intolerance, hyponatremia, and hyperkalemia. Testing revealed a low aldosterone level, high plasma renin activity, normal cortisol level, and normal 17-hydroxyprogesterone level. He was diagnosed with 18-hydroxylase deficiency based on low 18-hydroxycorticosterone levels and was treated with mineralocorticoid successfully for 17 months. At age 18 months, he presented with dehydration secondary to herpetic gingivostomatitis and was found to be hypoglycemic, hyponatremic, hyperkalemic, and acidotic, with a low serum cortisol level. An adrenocorticotropic hormone (ACTH) stimulation test revealed low levels of all adrenal cortex products, with an elevated ACTH level. He was started on glucocorticoids. Genetic testing confirmed X-linked adrenal hypoplasia congenita (AHC). His asymptomatic fraternal twin underwent genetic testing and the results were negative. The fertility center records indicated that the mother had donated eggs to other families, but none of the children were known to have this disorder. The egg donor was informed but did not pursue genetic testing.ConclusionWe report a case of X-linked AHC presenting in the context of extraordinary ethical considerations. Our case raises a question unique to the era of assisted reproduction: should routine genetic screening of gamete donors be done for rare but potentially life-threatening conditions? (Endocr Pract. 2014;20:e126-e129)     

Women with Nonclassic Congenital Adrenal Hyperplasia Have Gender,Sexuality, and Quality-Of-Life Features Similar to those of Nonaffected Women

Objective: Females with the severe classic forms of congenital adrenal hyperplasia reportedly have a higher frequency of atypical gender identity, nonheterosexual sexual relationships, and cross-gender role behavior. Comparable data and quality-of-life measures among those with the milder, more prevalent form, nonclassic congenital adrenal hyperplasia, are scarce. We aimed to assess health-related quality of life, gender identity, role, and sexual orientation in women with nonclassic congenital adrenal hyperplasia via a prospective, questionnaire-based, case-control study.Methods: Thirty-eight women with nonclassic congenital adrenal hyperplasia (median age 34 years; range, 18 to 44 years) and 62 age-matched female controls were recruited. Outcome measures included the Multi-Gender Identity, Sexuality, and World Health Organization (WHO) quality-of-life questionnaires.Results: Sociodemographic parameters (marital status, number of children, and educational level) were similar for both groups, as were most measures of the Multi-Gender Identity, Sexuality, and WHO quality-of-life questionnaires. However, “sometimes-feeling-as-a-man and sometimes-feeling-as-a-woman” were more frequently reported in the study group compared to the controls (7/38 [18.4%] vs. 3/62 [4.8%], respectively; P = .02). Furthermore, more nonclassic congenital adrenal hyperplasia women reported first falling in love with a woman (4/37 [10.8%] vs. 0/58 [0%]; P = .02).Conclusion: Our findings suggest possible subtle differences in gender identity and sexual orientation between adult nonclassic congenital adrenal hyperplasia females and controls. Quality of life was not impaired in individuals within the study group. The impact of exposure to mildly elevated androgen levels during childhood and adolescence on the female brain warrants more in-depth assessment in further studies.Abbreviations: CAH = congenital adrenal hyperplasia; Multi-GIQ = Multi-Gender Identity Questionnaire; NCCAH = nonclassic congenital adrenal hyperplasia; QoL = quality of life     

Mifepristone Treatment for Mild Autonomous Cortisol Secretion Due to Adrenal Adenomas: A Pilot Study

Objective: Adrenal incidentalomas are increasingly detected with the widespread use of thoracic and abdominal imaging. The most common secretory syndrome in adrenal nodules is autonomous cortisol secretion (ACS). Recent data show that even mild cortisol excess is associated with adverse outcomes. The glucocorticoid receptor antagonist mifepristone has been used in patients with overt Cushing syndrome and hyperglycemia. The purpose of our study was to determine the effect of mifepristone on metabolic parameters in patients with ACS and concomitant prediabetes or diabetes.Methods: Eight patients with either unilateral or bilateral adrenal nodules with ACS were included in the study. Fasting laboratory tests including glucose and insulin levels to calculate homeostatic model assessment for insulin resistance (HOMA-IR) were performed at baseline and again after either 3 months (3 patients) or 6 months (5 patients) on mifepristone 300 mg daily treatment. Patients also completed several validated surveys on mood and quality of life at baseline and follow-up.Results: There were significant reductions in fasting glucose measurements and insulin resistance as measured by HOMA-IR in the 6 of 8 study patients in whom these measurements were available (P = .03).Conclusion: This pilot study demonstrates that mifepristone treatment of ACS is associated with a significant decrease in fasting glucose and insulin resistance as measured by HOMA-IR scores. Mifepristone treatment of ACS may be considered as a medical option for patients with ACS due to adrenal adenomas with concomitant abnormal glucose parameters in whom surgical removal is not being considered.Abbreviations: ACS = autonomous cortisol secretion; ACTH = adrenocorticotropic hormone; AI = adrenal incidentaloma; DHEAS = dehydroepiandrosterone sulfate; GR = glucocorticoid receptor; HbA1c = hemoglobin A1c; HOMA-IR = homeostatic model assessment for insulin resistance; ODT = overnight dexamethasone suppression test; QoL = quality of life; STAI = state trait anxiety inventory; TSH = thyroid stimulating hormone; UFC = urinary free cortisol     

IMAGe association: additional clinical features and evidence for recessive autosomal inheritance

Congenital adrenal hypoplasia (CAH) normally occurs in the neonatal period, with patients presenting with more or less severe salt-wasting syndrome. X-linked CAH has been associated with mutations in the DAX-1 gene, and boys have also been shown to have hypogonadotrophic hypogonadism. Recently, in three unrelated boys, CAH was associated with intrauterine growth retardation (IUGR), metaphyseal dysplasia and genital abnormalities, defining a new association called IMAGe. We now report four additional patients with this association, including the first living female. The four patients belong to two unrelated families (one brother and one sister from each family). These patients have the main clinical characteristics of IMAGe association: IUGR, facial dysmorphy (frontal bossing, broad nasal bridge, low-set ears), short limbs due to metaphyseal dysplasia, and adrenal insufficiency. As these patients are older than the initial three patients, we can also describe additional features: short adult height, normal puberty in boys as well as in the living girl. The boys have hypospadias associated with micropenis. The living girl came to clinical attention at the age of 5 years as a result of a familial survey, and careful questioning revealed that she had been suffering from mild adrenal insufficiency since early childhood. At least one boy has congenital hypotonia due to muscular dystrophy. In conclusion, these four new cases display familial transmission, strongly suggesting Mendelian autosomal recessive inheritance. Adrenal insufficiency may be mild. Hypotonia, described in all the patients, might be related to paucisymptomatic muscular dystrophy, as this condition is clearly heterogeneous varying with regard to severity, associated manifestations and outcome. If this symptom is part of the syndrome, which we cannot assume, it could help to localize the candidate gene.     

Important Management Considerations In Patients With Pituitary Disorders During The Time Of The Covid-19 Pandemic

Objective: In December 2019, a novel coronavirus called severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) caused an outbreak of coronavirus disease 2019 (COVID-19) that resulted in a global pandemic with substantial morbidity and mortality. Currently, there is no specific treatment or approved vaccine against COVID-19. The underlying associated comorbidity and diminished immune function of some pituitary patients (whether caused by the disease and its sequelae or treatment with excess glucocorticoids) increases their risk of contracting and developing complications from COVID-19 infection.Methods: A review of studies in PubMed and Google Scholar published between January 2020 to the time of writing (May 1, 2020) was conducted using the search terms ‘pituitary,’ ‘coronavirus,’ ‘COVID-19’, ‘2019-nCoV’, ‘diabetes mellitus’, ‘obesity’, ‘adrenal,’ and ‘endocrine.’Results: Older age and pre-existing obesity, hypertension, cardiovascular disease, and diabetes mellitus increase the risk of hospitalization and death in COVID-19 patients. Men tend to be more severely affected than women; fortunately, most men, particularly of younger age, survive the infection. In addition to general comorbidities that may apply to many pituitary patients, they are also susceptible due to the following pituitary disorder–specific features: hypercortisolemia and adrenal suppression with Cushing disease, adrenal insufficiency and diabetes insipidus with hypopituitarism, and sleep-apnea syndrome and chest wall deformity with acromegaly.Conclusion: This review aims to focus on the impact of COVID-19 in patients with pituitary disorders. As most countries are implementing mobility restrictions, we also discuss how this pandemic has affected patient attitudes and impacted our decision-making on management recommendations for these patients.Abbreviations: ACE = angiotensin-converting enzyme; AI = adrenal insufficiency; ARB = angiotensin receptor blocker; ARDS = acute respiratory disease syndrome; COVID-19 = coronavirus disease 2019; CPAP = continuous positive airway pressure; DI = diabetes insipidus; DM = diabetes mellitus; SARS-CoV-2 = severe acute respiratory syndrome coronavirus 2     

Genetics of Primary Aldosteronism

Objective: The American Association of Clinical Endocrinologists Adrenal Scientific Committee has developed a series of articles to update members on the genetics of adrenal diseases.Methods: Case presentation, discussion of literature, table, and bullet point conclusions.Results: Primary aldosteronism (PA) is the most common form of secondary hypertension. Early detection, surveillance, and treatment of PA may mitigate future cardiovascular risk. The genetics of PA are rapidly evolving, and the consideration for genetic causes of PA are growing. Three inheritable forms of PA are now recognized: familial hyperaldosteronism type I (glucocorticoidremediable aldosteronism), familial hyperaldosteronism type II, and familial hyperaldosteronism type III. The recent discovery of familial hyperaldosteornism type III spurred a flurry of international and collaborative research that is identifying more genetic and molecular causes of PA that relate to mutations in membrane electrolyte transport channels of zona glomerulosa cells.Conclusion: This article reviews the various genetic forms of PA, including a focus on the molecular mechanisms involved, diagnosis, and treatment.Abbreviations: ACTH = adrenocorticotropic hormone ARR = aldosterone to renin ratio FH-I = familial hyperaldosteronism type I FH-II = familial hyperaldosteronism type II FH-III = familial hyperaldosteronism type III GRA = glucocorticoidremediable aldosteronism PA = primary aldosteronism PRA = plasma renin activity     

Morning Serum Cortisol Level After Transsphenoidal Surgery for Pituitary Adenoma Predicts Hypothalamic-Pituitary-Adrenal Function Despite Intraoperative Dexamethasone Use

Objective: Perioperative glucocorticoid (GC) is rarely needed in patients undergoing transsphenoidal surgery (TSS). We instituted a steroid-sparing protocol in the settings of intraoperative dexamethasone use. We evaluated the safety of using a cut off cortisol level of 14 μg/dL on postoperative day (POD)-1 and -6 after dexamethasone use during the surgery. We also analyzed the efficacy of serial morning cortisol levels for weaning GC replacement.Methods: The charts of 48 adult patients who received dexamethasone 4 mg intraoperatively were reviewed. Morning cortisol levels were measured on POD-1. Patients with cortisol ≥14 μg/dL were discharged without CG replacement. Morning cortisol level was checked routinely on POD-6, and GC replacement was initiated when the level was <14 μg/dL. Serial cortisol levels were measured in patients requiring GC after the first postoperative week.Results: Overall, 67% patients had POD-1 cortisol ≥14 μg/dL and did not require GC on discharge. After POD-6, 83% of patients were not on GC replacement. A cosyntropin stimulation testing (CST) was only performed in 3 patients. There were no hospital admissions for adrenal crisis during the postoperative period.Conclusion: A steroid-sparing protocol with POD-1 and -6 morning cortisol levels can be safely and effectively used in the settings of intraoperative dexamethasone administration. It leads to avoidance of GC in more than two-thirds of patients on discharge and more than 80% of patients after the first postoperative week. We found that dynamic adrenal testing could be omitted in the majority of patients by using serial morning cortisol levels to assess the hypothalamic-pituitary-adrenal (HPA) axis.Abbreviations: ACTH = adrenocorticotropic hormone AI = adrenal insufficiency CST = cosyntropin stimulation test ECLIA = electrochemiluminescence immunoassay GC = glucocorticoid HPA = hypothalamic-pituitary-adrenal ITT = insulin tolerance test POD = postoperative day TSS = transsphenoidal surgery