The prevalence and characteristics of non-functioning and autonomous cortisol secreting adrenal incidentaloma after patients’ stratification by body mass index and age

We aimed to evaluate the prevalence and characteristics of NFAI and ACS after the study population stratification by different BMI and age groups.

We conducted a retrospective cross-sectional study including all patients with AI referred to University Medical Centre from January 2005 to January 2012. After that period, the majority of patients with AI were managed in our outpatients’ clinics. The study was conducted in accordance with the Declaration of Helsinki, approved by the National Ethical Committee.

We identified 769 adult patients with documented diagnosis of AI. The medical records of all patients were reviewed by the authors to confirm the diagnosis of AI based on European Society of Endocrinology Clinical Practice Guideline for management of AIs [1] and divided them into NFAI and ACS. NFAI was considered when cortisol after overnight dexamethasone (ODST) suppression test was < 50 nmol/l, ACS when cortisol was ≥50 nmol/l [1] and there were no typical clinical signs of Cushing’s syndrome. One to three consultants that were experienced in the diagnosis of Cushing syndrome excluded typical catabolic signs of hypercortisolism. Included AI had radiological features of lipid-rich, benign adrenal adenoma as defined with Hounsfield units (HU) of ≤10 for noncontrast CT [16] or a relative washout > 40% and an absolute washout > 60% for contrast-enhanced washout CT, when an attenuation value for unenhanced CT was > 10 HU [17] or benign characteristic in magnetic resonance imaging (MRI) [18]. We excluded suspected metastasis, adrenal carcinoma, lipoma, pheochromocytoma, adrenal hyperplasia and patients with primary hyperaldosteronism. In addition, we excluded all patients with symptomatic cholecystolithiasis and pancreatitis. Among exclusion criteria were also patients under treatment with the drugs that significantly interfere with measured variables including oral hormonal contraceptives, glucocorticoids, mineralocorticoid antagonists and potassium-wasting diuretics. Some less interfering antihypertensive medications and lipid lowering agents were not consistently discontinued before measuring aldosterone and PRA. Subjects with hereditary syndromes associated with adrenal tumors were also excluded. The Flowchart of the study is presented in Fig. 1.

The following data were collected from the hospital documentation system: patient gender, age at diagnosis, weight, height, method of radiological assessment of AI (computed tomography, magnetic resonance), size of AI, site of AI (left, right, or bilateral), Hounsfield units, blood pressure, heart rate, baseline cortisol and cortisol after ODST, baseline ACTH, baseline DHEAS, DHEAS after ODST, aldosterone, PRA, TSH, fasting glucose, lipids (cholesterol, HDL, LDL, triglycerides). Normal levels of baseline cortisol were defined as 138–690 nmol/l, cortisol after ODST < 50 nmol/l, ACTH < 10.2 pmol/l, DHEAS 3.6–12.9 μmol/L, aldosterone 0.134–0.751 nmol/l, PRA 0.6–4.84 μg/l/h, TSH 0.59–4.29 mE/l, fasting glucose 3.6–6.1 mmol/liter, cholesterol < 5.2 mmol/liter, HDL > 1 mmol/liter, LDL < 3.4 mmol/liter, triglycerides < 1.7 mmol/liter. Among additional biochemical parameters we included creatinine, natrium and leucocytes count since they have been included into the risk estimator for adrenal tumor functionality [19]. The data collection contained 11,132 points.

Cortisol was determined using IMMULITE® 2000 Cortisol assay. Intra-assay variations were ≤ 15% and inter-assay variations were ≤ 20% for the applied methods. DHEAS was measured by specific double antibody RIA using 125 I-labeled hormones (Diagnostic Systems Laboratories, Webster, TX, USA). Intra-assay coefficient variation (CV) for DHEAS ranged from 4.9 to 9.8% and inter-assay CV from 7.9 to 13.0%. Aldosterone was determined using ACTIVE® Aldosterone RIA for serum samples. Intra-assay variations were ≤ 4.5% and inter-assay variations were ≤ 9.8% for the applied methods. PRA was determined using Angiotensin I RIA KIT for serum samples. Intra-assay variations were ≤ 8% and inter-assay variations were ≤ 10% for the applied methods. ACTH was determined using IMMULITE® 2000 ACTH system. Intra-assay variations were ≤ 9.5% and inter-assay variations were ≤ 10% for the applied methods. TSH was determined using ADVIA Centaur CP TSH3-Ultra assay. Intra-assay variations were ≤ 16.7% and inter-assay variations were ≤ 22.3% for the applied methods. Fasting glucose levels were determined using the standard glucose oxidase method (Beckman Coulter Glucose Analyzer, Beckman Coulter Inc., CA, USA). Lipids were determined using Adiva 1800, Siemens analyzer. Intra-assay variations ranged from 1.6 to 6.3%, and inter-assay variations ranged from 5.8 to 9.6% for the applied methods. Creatinine, natrium, leucocytes count were assessed with routine biochemical evaluation after 12-h overnight fast. CT evaluation included maximum diameter of incidentaloma, laterality, presence of necrosis, calcifications, atypical characteristics. MR report included evaluation of maximum diameter of the tumor and laterality. BMI was calculated as the weight in kilograms divided by square of height in meters. Blood pressure was measured with sphygmomanometer using appropriate cuff size.

The results for continuous variables are presented as means and standard deviation (SD) or median and interquartile range. The results for categorical variables are presented as frequencies. Spearman’s rho was used to assess correlation between continuous variables, while Fisher’s exact test was used to assess the association between categorical variables. To compare continuous variables between different groups, nonparametric Mann-Whitney test or Kruskal-Wallis and pairwise comparisons with post hoc Bonferroni corrections were used. To calculate prevalences, population data from SI-STAT (https://​pxweb.​stat.​si/​) database was used. P values below 0.05 were considered statistically significant. Statistical analysis was performed using IBM SPSS Statistics, version 21.0 (IBM Corporation, Armonk, New York, USA).

The study population consisted of 432 patients (179 (41.4%) male, 253 (58.6%) female) of median age 63.4 (54.0–71.6) years, median body mass 77.6 (67.4–88.8) kg and median BMI 28.6 (25.5–31.7) kg/m². We identified 290 patients with NFAI and 142 with ACS, among which 128 had cortisol after overnight dexamethasone (ODST) suppression test between 50 nmol/l and 138 nmol/l and 14 had cortisol levels post dexamethasone > 138 nmol/L.

In majority of subjects, AI was diagnosed by CT (388 (92.2%)), in the rest by MRI [11 missing data]. 183 (43.9%) of patients presented with right-sided AI, 147 (35.3%) with left sided AI. In 87 (20.9%) AI was observed bilaterally [15 missing data]. Median size of right sided AI was 25 [19‐30] mm and of left sided was 20 [15‐30] mm. Size of the AI did not correlate with the presence of diabetes mellitus type 2 (presented in 52 (12.0%) patients), nor in NFAI or in ACS group (both P-values > 0.05).

In NFAI group 243 subjects had one-side AI, 47 had bilateral adrenal mass. One-sided NFAI did not differ from bilateral NFAI in any of the anthropometric, clinical, hormonal, biochemical or radiologic characteristics (all P-values > 0.05). In ACS group 102 subject had one-side AI, 40 had bilateral adrenal mass. One-sided ACS had lower cholesterol (P = 0.021) and left-sided AI in patients with bilateral ACS were smaller than left-sided AI in patients with unilateral ACS (P = 0.025). One-sided ACS did not differ from bilateral ACS in any other anthropometric, clinical, hormonal, biochemical or radiologic characteristics (all P-values > 0.05).

The comparison of selected parameters between NFAI and ACS is outlined in Table 1. Patients with ACS were older (P = 0.008), with higher basal cortisol level (P < 0.001), lower basal DHEAS (P = 0.001), lower DHEAS after ODST (P = 0.027) and higher aldosterone (P = 0.039). They had slightly lower weight (P = 0.023). AIs with ACS were significantly larger than NFAI (P < 0.001). There was no significant difference in gender distribution, ACTH, PRA, TSH, creatinine, sodium and leukocytes between patients with ACS and NFAI (all P-values > 0.05). We observed no significant difference between NFAI and ACS groups regarding BMI, blood pressure, heart rate, lipid profile, fasting glucose and presence of diabetes mellitus type 2 (all P-values > 0.05).

In NFAI group, younger patients have lower blood pressure, lower body mass, LDL, fasting glucose, lower creatinine, basal DHEAS and DHEAS after ODST in comparison with older patients. There were significantly more younger women than man (P = 0.032). The data are provided in Table 2. TSH levels differed significantly among age groups (P < 0.001), with highest values in patients aged 60–69 years and lowest values in patients over 79 years. There were no differences in leukocyte concentration (P = 0.958).

In ACS group, younger subjects significantly differ from older in blood pressure, cholesterol, LDL, fasting glucose, creatinine. The data are provided in Table 3. TSH levels differed significantly among age groups (P < 0.001), with highest values in patients aged 60–69 years and lowest values in patients aged 70–79 years. There were no differences in leukocyte concentration (P = 0.425).

When stratified by BMI (≤ 25 kg/m², 25–30 kg/m² and > 30 kg/m²), patients with NFAI and higher BMI, had higher fasting glucose (P < 0.001, pairwise comparison BMI ≤ 25 kg/m² vs. BMI > 30 kg/m²P < 0.001, 25–30 kg/m²P = 0.050), lower HDL (P = 0.009, pairwise comparison BMI ≤ 25 kg/m² vs. BMI > 30 kg/m²P = 0.007), higher triglycerides (P = 0.001, pairwise comparison BMI ≤ 25 kg/m² vs. BMI > 30 kg/m²P < 0.001), higher creatinine (P = 0.008, pairwise comparison BMI ≤ 25 kg/m² vs. BMI > 30 kg/m²P = 0.032, 25–30 kg/m²P = 0.050) (P = 0.023) and higher leukocytes (P = 0.014, pairwise comparison BMI ≤ 25 kg/m² vs. BMI > 30 kg/m²P = 0.019). There were significantly more patients with diabetes mellitus in higher BMI groups (P = 0.002).

When stratified by BMI patients with ACS and different BMI (≤ 25 kg/m² vs. 25–30 kg/m² vs. > 30 kg/m²), differed in TSH (P = 0.006, pairwise comparison BMI 25–30 kg/m² vs. BMI > 30 kg/m²P = 0.005), HDL (P = 0.006, pairwise comparison BMI 25–30 kg/m² vs. BMI > 30 kg/m²P = 0.005) and creatinine (P = 0.012, pairwise comparison BMI ≤ 25 kg/m² vs. BMI > 30 kg/m²P = 0.0471, 25–30 kg/m² vs. BMI > 30 kg/m²P = 0.011). Patients with ACS across the three BMI groups (≤ 25 kg/m², 25–30 kg/m² and > 30 kg/m²) did not differ in age, basal cortisol, basal DHEAS and DHEAS after ODST, aldosterone, PRA, TSH, blood pressure, heart rate, fasting glucose, cholesterol, triglycerides, LDL, sodium and leukocytes. There was no significant difference in gender distribution between groups (P > 0.05). Regression analysis did not show any significant correlation between BMI and presence of diabetes mellitus in this group (OR = 1.00, 95% CI = 0.90–1.12, P = 0.969).

BMI > 25 kg/m² had 100% of patients aged 25–29 years, 81.8% patients aged 40–44 years, 68.4% patients aged 45–49 years, 77.3% patients aged 50–54 years, 81.8% patients aged 55–59 years, 75.8% patients aged 60–64 years, 86.8% patients aged 65–69 years, 73.7% patients aged 70–74 years, 76.2% patients aged 75–79 years, 68.4% patients aged 80–84 years. Only in 2 age groups at the tails of age distribution, AIs were more common in normal weight than in overweight/obese group (2/2 patients in age group 30–34 years 66.7% had BMI ≤ 25 kg/m² and 1/1 patient aged over 84 years had BMI ≤ 25 kg/m². However, number of the subjects in these two groups were neglectable (Fig. 2).

In group with ACS, BMI > 25 kg/m² had 100% of patients aged 25–29 and 35–39 years, 40% of patients aged 40–44 years, 66.7% % of patients aged 45–49 years, 70.6% of patients aged 50–54 years, 87.5% of patients aged 55–59 years, 45.5% of patients aged 60–64 years, 77.8% of patients aged 65–69 years, 92.9% of patients aged 70–74 years, 90% of patients aged 75–79 years, 92.3% of patients aged 80–84 years. The only patient aged over 84 years had BMI ≤ 25 kg/m² (Fig. 2).