Acute adrenal crisis and hypercalcemia in a patient assuming high liquorice doses.

Two months after monolateral adrenalectomy, a 47-year-old woman stopped taking corticosteroid replacement therapy in the first 15 days of therapy. She was admitted to the Department of Internal Medicine because of hypertension, severe hypercalcemia, uncompensated metabolic alkalosis and clinical symptoms of acute adrenal insufficiency. The presence of hypokalemia and hypernatremia precluded a diagnosis of hypocortisolism, therefore no corticosteroids were given during the time required to investigate the cause of hypercalcemia, which resulted negative. Administration of intravenous saline infusion produced no improvement in her clinical condition. Despite electrolyte alterations, hydrocortison (100 mg i.v.) and zoledronate (4 mg i.v.) were also administered, leading to a rapid and marked improvement in her clinical picture within a few hours, with normalization of the calcemia and the other electrolytic disturbances. After her neurological condition had fully normalized, the patient admitted she had been assuming large amounts of liquorice as a laxative for many years; this compound very likely compensated the adrenal insufficiency by inhibiting 11 b steroid-dehydrogenase and disguised the clinical presentation at the time of admission. This case report confirms that, though rare, hypercalcemia may be a finding in acute adrenal insufficiency and can be rapidly corrected by corticosteroid administration. Furthermore, excessive liquorice intake can induce a clinical picture resembling that of primary hyperaldosteronism. In patients with adrenal insufficiency, it can, at least in part, disguise its metabolic effects and delay diagnosis and treatment.

Primary hyperaldosteronism is associated with derangement in the regulation of the hypothalamus-pituitary-adrenal axis in humans.

Hippocampal mineralocorticoid receptors (MR) play a major role in the control of hypothalamus- pituitary-adrenal (HPA) axis. The functional profile of HPA axis and the impact of MR blockade under chronic exposure to mineralocorticoid excess are unknown. To clarify this issue, ACT H, cortisol, and aldosterone secretions were studied in 6 patients with primary hyperaldosteronism (HA) and 8 controls (NS) during placebo, placebo+human CR H (hCR H) (2 microg/kg iv bolus at 22:00 h), potassium canrenoate (CAN, 200 mg iv bolus at 20:00 h followed by 200 mg infused over 4 h) or CAN+hCR H. During placebo, both aldosterone and ACT H levels were higher (p<0.01) in HA than in NS, while cortisol levels were not significantly different. Both HA and NS showed significant ACT H and cortisol responses to hCR H (p<0.004), although the hormonal responses in HA were higher (p<0.02) than in NS. CAN infusion did not modify aldosterone levels in both HA and NS. Under CAN infusion, ACT H showed progressive rise in NS (p<0.05) but not in HA, while cortisol levels showed a significant (p<0.05) but less marked and delayed increase in HA compared to NS. CAN enhanced hCRH-induced ACTH and cortisol responses in NS (p<0.05), but not in HA. In conclusion, in humans primary hyperaldosteronism is associated with deranged function of the HPA axis. In fact, hyperaldosteronemic patients show basal and hCR H-stimulated HPA hyperactivity that is, at least partially, refractory to further stimulation by mineralocorticoid blockade with canrenoate. Whether this hormonal alteration can influence the clinical feature of hypertensive patients with primary hyperaldosteronism needs to be clarified.

Failure of angiotensin II and insulin to stimulate transforming growth factor-beta1. Release from cultured bovine retinal pericytes.

BACKGROUND: Activation of the renin-angiotensin system (RAS) may induce cardiovascular and renal fibrosis in hypertension and diabetes. This fibrogenic effect is mainly mediated by Transforming Growth Factor-B1 (TGF-B1), a multifunctional citokyne released by endothelial, vascular smooth muscle and renal mesangial cells, that is able to increase extracellular matrix deposition. Retinal capillary pericytes have functions similar to those of mesangial cells, including ability to synthesize and release TGF-B1 and produce extracellular matrix. An intraocular RAS was described in the human eye and may produce effects similar to those observed in the heart and kidney, which could be mediated by TGF-B1. In particular, TGF-B1 might be involved in thickening of the capillary basement membrane in diabetic microangiopathy. We therefore aimed at evaluating the possible effects of Angiotensin-II on TGF-B1 secretion by cultured retinal pericytes (BRP). METHODS: BRP cultures were incubated with Angiotensin-II or insulin (known to play a permissive effect on TGF-B1 release from mesangial cells) or Angiotensin-II + insulin at final concentrations of 10-10, 10-8, 10-6, 10-4 mol/L. RESULTS: Baseline TGF-B1 concentrations in the supernatants of pericyte cultures were 6 139 +/- 1 919 pg/mL/106 cells; no changes of TGF-B1 concentrations resulted from adding increasing amounts of Ang II, insulin or both. CONCLUSIONS: Though confirming that cultured bovine retinal pericytes spontaneously release TGF-B1, Angiotensin-II did not produce any stimulatory effects of in our experimental system