Background Primary aldosteronism (PA) is a common but under‐recognized cause of secondary hypertension. Data directly comparing screening rates across single and overlapping indications are lacking. Methods and Results We conducted a retrospective review of adults with hypertension seen in outpatient clinics at a tertiary referral academic center between January 1, 2017, and June 30, 2020. We included patients with hypertension plus at least one of the following: resistant hypertension; age<35 years; obstructive sleep apnea; hypokalemia; or an adrenal mass. We excluded patients with adrenal insufficiency, severe renal disease, or heart failure, and renovascular hypertension. Of 203 535 patients with hypertension, 86044 (42.3%) met at least 1 PA screening criterion, and of these, 2898 (3.4%) were screened for PA. Screening occurred in 2.7% of patients with resistant hypertension; 4.2% of those with obstructive sleep apnea; 5.1% of those <35 years; 10.0% of those with hypokalemia; and 47.3% of patients with an adrenal mass. Screening rates were higher in patients with multiple risk factors: 16.8% for ≥3, 5.7% for 2, and 2.5% for 1 criterion. Multiple logistic regression showed that the odds of PA screening were higher in patients with hypokalemia: odds ratio (95% CI): 3.0 (2.7–3.3); women: 1.3 (1.2–1.4); Black versus White: 1.5 (1.4–1.7); those with obstructive sleep apnea, chronic renal disease, stroke, and dyslipidemia. Conclusions Consideration for PA is given in a small subset of at‐risk patients, and typically after comorbidities have developed.
Background Hypertension is estimated to affect 1: 2 adults in the USA, and secondary hypertension accounts for up to 40% cases. Pheochromocytomas and paragangliomas (PPGL) are thought to be rare causes of hypertension, although their true prevalence might be underestimated. Less than half of patients with PPGL have prototypical symptoms. PPGL can lead to serious complications, including death, particularly if unrecognized. Expert guidelines recommend screening for secondary causes of hypertension in patients with resistant hypertension, patients with early-onset hypertension, and in those with hypertension and an adrenal mass. The rates of PPGL screening are unknown. Objective To evaluate the rates and patterns of PPGL screening among candidate patients. Methods We conducted a retrospective review of adult patients (age ≥ 18 years) with hypertension seen in a university-based outpatient setting between 01/01/2017 - 06/30/2020, and we included patients with: 1) resistant hypertension (uncontrolled hypertension while taking at least 3 antihypertensive agents OR taking ≥4 antihypertensive agents); 2) hypertension at age <35 years; 3) adrenal nodule(s). We excluded patients with renovascular hypertension, advanced chronic kidney disease (CKD stage ≥4), stage III and IV heart failure, adrenal insufficiency, and congenital adrenal hyperplasia. Results Of 203,535 patients with hypertension, 71,088 (35%) met at least one of the above criteria, and only 2013 (2.83%) were screened for PPGL. Overall, patients screened were younger (56.2 ± 17.4 vs. 63.9±17.1 years, p <0.001), more often women (54.1% vs. 44.2%, p=0.001), and non-smokers (54.6% vs. 47.5%, p<0.001) than those not screened. While most patients included in the study were white (80%), the proportion of black patients was larger among those screened (19.9% vs.13.3% of those not screened, p<0.001). Of the three indications for PPGL screening, the rates were highest in patients with hypertension and adrenal nodule(s) (51.7%), while patients with early onset hypertension and those with resistant hypertension were rarely screened (3.9% and 2.4%, respectively). Multivariable logistic regression with LASSO selection showed that the odds of PPGL screening were higher in black vs. white patients (1.35 [1.19-1.53]); those who never smoked (1.68 [1.41-2.00]); patients with stroke (1.34 [1.16-1.54]); dyslipidemia (1.41 [1.26-1.57]), CKD (1.40 [1.26-1.56); obstructive sleep apnea (1.96 [1.76-2.19]); and adrenal nodules (55.1 [44.53-68.17]). Conclusions Screening for PPGL is conducted in roughly half of patients with adrenal nodules and hypertension, but rarely in patients with resistant or early onset hypertension. Screening occurs more often in patients with complications known to be associated with PPGL, including cardiovascular accidents. Presentation: Sunday, June 12, 2022 12:30 p.m. - 2:30 p.m., Monday, June 13, 2022 1:12 p.m. - 1:17 p.m.
Primary Hyperaldosteronism: Screening, Diagnosis, and Management for the Clinician
Primary hyperaldosteronism (PA) is the most common secondary, non-iatrogenic cause of hypertension. This condition is associated with significant risk of morbidity and mortality, yet it is often unrecognized and undiagnosed in the primary care setting. Screening with the aldosterone to renin ratio (ARR) should be considered in patients with resistant hypertension, defined as blood pressure >140/90 mmHg despite the use of three different classes of antihypertensive medications, including a diuretic. The goal of this review is to inform the primary care clinician of the current guideline recommendations for screening, confirming, subtyping, and treating primary hyperaldosteronism.
Background: Tumor-generated ectopic intact PTH is difficult to diagnose and should be suspected in patients with apparent primary hyperparathyroidism but with normal parathyroid glands. Clinical Case: A 72-year-old man presented with symptoms of hypercalcemia including generalized weakness, polyuria, and polydipsia. Initial labs were consistent with primary hyperparathyroidism: calcium 12.1 mg/dL (n 8.6–10.3 mg/dL, albumin-corrected 12.5 mg/dL), intact PTH (iPTH) 115.6 pg/mL (n 10–65 pg/mL), low normal 25-OH vitamin D (25 ng/mL, n 25–100 ng/mL), and relatively high normal 1,25 dihydroxyvitamin D (52 pg/mL, n 18–78 pg/mL). 24-hour urine calcium was 381 mg/day (n 100–300 mg/day) and PTHrP was 1.6 pmol/L (n <4.2 pmol/L). Neck ultrasound demonstrated a 0.5 x 1 cm hypoechoic mass near right thyroid inferior pole, though sestamibi SPECT/CT scan did not reveal scintographic evidence of a parathyroid adenoma. He underwent subtotal parathyroidectomy with largest excised gland weighing 0.262 grams. The left inferior parathyroid gland appeared normal intraoperatively, thus was clipped and left in place. PTH decreased from 194 pg/mL to 98 pg/mL postoperatively. Pathological examination revealed three normocellular parathyroid glands with enlargement of only the right superior gland. Venous sampling of the parathyroid vasculature failed to identify the source of autonomous iPTH post operatively. Due to refractory hypercalcemia, cinacalcet was initiated. However, hypercalcemia as high as 12.6 mg/dl and hyperparathyroidism to 672 pg/mL persisted despite dose escalation. He eventually received pamidronate with subsequent transition to denosumab due to declining renal function. A 68Ga DOTATATE scan was performed to locate occult ectopic parathyroid, which reported multiple foci of presumed somatostatin receptor expression involving the liver and intra-abdominal lymph nodes without significant uptake in the neck concerning for metastatic disease. Liver lesion biopsy was consistent with pancreato-biliary adenocarcinoma. Surprisingly, the biopsy was negative for iPTH and neuroendocrine tumor markers on staining/immunohistochemistry. Given his poor prognosis and multiple comorbidities, the patient opted not to pursue any further workup or therapy for his malignancy. Conclusion: Occult malignancy should be suspected for a patient with persistent hyperparathyroidism after parathyroidectomy. Treatment of the malignancy may lead to an improvement in hypercalcemia and iPTH levels. Employment of iPTH mRNA testing or intra-abdominal venous sampling to prove ectopic iPTH secretion would be ideal, as iPTH staining could be falsely negative. Further testing was not completed as the patient declined further evaluation.
Background Pheochromocytomas and paragangliomas (PPGL) are rare causes of secondary hypertension, but when unrecognized, they can lead to serious complications. Data regarding PPGL screening are lacking. Objective To assess the rates and patterns of PPGL screening among eligible patients. Subjects and Study Design We conducted a retrospective review of adults with hypertension seen in outpatient clinics of a large academic center between 01/01/2017 - 06/30/2020. We included patients with treatment-resistant hypertension, hypertension at age <35 years, and/or adrenal mass(es). Results Of 203,535 patients with hypertension identified, 71,088 (35%) met ≥1 inclusion criterion(a), and 2,013 (2.83%) were screened for PPGL. Patients screened were younger (56.2 ± 17.4 vs. 64.0 ± 17.1 years), more often women (54.1% vs. 44.2%), and never-smokers (54.6% vs. 47.5%, p < 0.001 for all). The rate of screening was highest in patients with hypertension and adrenal mass(es) (51.7%, vs. 3.9% in patients with early-onset hypertension, and 2.4% in those with treatment-resistant hypertension). Multivariable logistic regression showed higher odds of PPGL screening in women (OR [95% confidence interval, CI]: 1.48 [1.34 - 1.63]); black vs. white patients (1.35 [1.19-1.53]); patients with adrenal mass(es) (55.1 [44.53-68.15]), stroke (1.34 [1.16-1.54]), dyslipidemia (1.41 [1.26-1.58]), chronic kidney disease (1.40 [1.26-1.56]), and obstructive sleep apnea (1.96 [1.76-2.19]). Conclusions PPGL screening is pursued in roughly half of patients with adrenal nodules and hypertension, but rarely in patients with treatment-resistant or early-onset hypertension. Like for other forms of secondary hypertension, PPGL screening occurs more often after serious complications develop.
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