Eculizumab treatment: stochastic occurrence of C3 binding to individual PNH erythrocytes

C5 blockade by eculizumab prevents complement-mediated intravascular hemolysis in paroxysmal nocturnal hemoglobinuria (PNH). However, C3-bound PNH red blood cells (RBCs), arising in almost all treated patients, may undergo extravascular hemolysis reducing clinical benefits. Despite the uniform deficiency of CD55 and of CD59, there are always two distinct populations of PNH RBCs, with (C3+) and without (C3-) C3 binding

Relative contributions of inferior petrosal sinus sampling and pituitary imaging in the investigation of children and adolescents with ACTH-dependent Cushing's syndrome.

Selective transsphenoidal microadenomectomy is the first line treatment of childhood Cushing's disease, with accurate preoperative localization of the corticotroph adenoma an important step in its investigation. Inferior petrosal sinus sampling (IPSS) for ACTH after CRH stimulation is a recognized investigation in adults, but there are few data in the pediatric age range. We report the relative contributions of IPSS and pituitary imaging in 11 patients, aged 10.7-18.8 yr, presenting with Cushing's disease. All underwent transsphenoidal surgery (TSS). IPSS was performed without complication. Sampling was from the inferior petrosal sinuses in 7 patients and the high jugular veins in 4 (patients 2, 4, 5, and 10). The central to peripheral ACTH (IPS/P) ratios were more than 2 (2.5-157.2) in 10 of 11 patients, confirming central ACTH secretion. In 3 patients with high jugular sampling, IPS/P ratio ranged from 2.5-21.1. In the fourth patient with high jugular sampling (IPS/P ratio, 0.95), a central adenoma was identified surgically, and the patient was cured after TSS. The interpetrosal sinus ACTH gradient (IPSG) was more than 1.4 (2.1-20.8) in 10 patients, indicating lateralization of ACTH secretion to the right side in 6 patients and to the left in 4. IPSG ratios were 2.1-8.5 in 3 patients with high jugular sampling. Pituitary imaging (computed tomography and or magnetic resonance imaging) was reported to identify an adenoma in 5 of 11 patients. At operation a tumor was visualized by the same surgeon in all 11 cases. In 9 patients with lateralization on IPSS, the correct side of the tumor was confirmed at surgery. In a 10th patient with a negative IPSG, a central tumor was present. Thus, IPSS gave a 91% prediction of correct tumor localization. In only 1 of 5 patients with an adenoma reported on pituitary imaging was this localization confirmed at surgery, a prediction rate of only 9%. After TSS, 8 patients were cured, 1 was in remission, and 2 required pituitary irradiation. In 73% of patients undergoing IPSS, localization of the adenoma was followed by surgical cure or remission. Pituitary scanning was therefore relatively unhelpful in localizing the adenoma. In experienced hands, however, IPSS was feasible in this age group, safe, and strongly predictive of the site of the adenoma, leading to a high rate of successful surgical outcome

Is ovarian and adrenal venous catheterization and sampling helpful in the investigation of hyperandrogenic women?

OBJECTIVE: To audit our practice of performing ovarian and adrenal venous catheterization and sampling in hyperandrogenic women who fail to suppress their elevated androgen levels following a 48-h low-dose dexamethasone suppression test (LDDST). We considered the technical success rate of catheterization, the extra information obtained in addition to the standard biochemical tests and imaging findings, and the impact of sampling on management decisions. DESIGN: A retrospective analysis of the results of all ovarian and adrenal venous catheterizations performed at St Bartholomew's Hospital, London, in the years 1980-1996. PATIENTS AND METHODS: Baseline ovarian and adrenal androgens were measured in all women presenting with symptoms and signs of hyperandrogenism. Those patients who failed to suppress their elevated testosterone (T), androstenedione (A4) and/or dehydroepiandrosterone-sulphate (DHEAS) levels following a LDDST to within the normal range or to less than 50% of the baseline value were investigated further with adrenal computed tomography (CT), ovarian ultrasound, and ovarian and adrenal venous catheterization and sampling. RESULTS: Results were available in 38 patients. The overall catheterization success rate was: all four veins in 27%, three veins in 65%, two veins in 87%. The success rate for each individual vein was: right adrenal vein (RAV) 50%, right ovarian vein (ROV) 42%, left adrenal vein (LAV) 87% and left ovarian vein (LOV) 73%. Eight patients were found to have tumours by means of imaging (adrenal CT and ovarian ultrasound), three adrenal and five ovarian, seven of which underwent operation. In six of these patients the clinical presentation was suggestive of the presence of a tumour; in addition, the combination of imaging findings allowed the detection of suspicious adrenal and ovarian masses in all eight cases. The five patients with ovarian tumours had serum testosterone levels > 4.5 nmol/l. In a further eight patients, laparotomy was performed based on a combination of diagnostic and therapeutic indications; in two of these patients the catheterization results were suggestive of an ovarian tumour. All these eight patients were shown histologically to have polycystic ovarian syndrome (PCOS), and no occult ovarian tumour was identified. None of the patients with nontumourous hyperandrogenism had a baseline testosterone level in excess of 7 nmol/l (median 4.4 nmol/l, range 2.5-7 nmol/l). CONCLUSIONS: Our results suggest that ovarian and adrenal venous catheterization and sampling should not be performed routinely in women presenting with symptoms and signs of hyperandrogenism, even if they fail to suppress their elevated androgen levels to a formal 48-h LDDST. All patients presenting with symptoms and signs of hyperandrogenism and elevated androgen levels, and where the suspicion of an androgen-secreting tumour is high, should have adrenal CT and ovarian ultrasound imaging to detect such a tumour. Venous catheterization and sampling should be reserved for patients in whom uncertainty remains, as the presence of a small ovarian tumour cannot be excluded on biochemical and imaging studies used in this series alone. Its use should be restricted to units with expertise in this area

Bilateral phaeochromocytomas in von Hippel-Lindau disease: diagnosis by adrenal vein sampling and catecholamine assay.

Three unrelated patients with von Hippel-Lindau disease had phaeochromocytomas diagnosed as a result of screening in their third decade. All had raised 24-h urinary noradrenaline levels and obvious unilateral adrenal tumours on ultrasound scanning and computed tomography. The contralateral adrenal appeared either normal or equivocally abnormal using the same imaging techniques. Radiolabelled meta-iodo-benzylguanidine uptake and enhanced T2-weighted magnetic resonance signals confirmed the ipsilateral lesion, but showed no abnormality in the contralateral adrenal. Nevertheless, venous sampling demonstrated abnormally elevated noradrenaline:adrenaline ratios (normal < 1) in blood draining both adrenals in all three patients. All underwent bilateral adrenalectomy: histological examination confirmed bilateral phaeochromocytomas in all three patients, with the smaller adrenal showing tumours between 3 and 11 mm in diameter. A fourth patient with von Hippel-Lindau disease was also evaluated because of a left 'suprarenal' mass discovered by ultrasound scanning. Urinary and plasma catecholamines were normal. Computed tomography showed a normal right adrenal, with a left para-aortic mass lying superior to the left adrenal. Magnetic resonance scanning showed an enhanced T2 signal from the mass, which also showed positive uptake with radiolabelled mIBG. At operation, a non-secretory left para-aortic paraganglioma was found. Venous sampling suggested that the left adrenal was normal, and this was confirmed on histology. Venous sampling for catecholamine assays is effective in locating small bilateral phaeochromocytomas and defining a normal adrenal gland, and can be useful in preventing unnecessary or repeat operations in patients with non Hippel-Lindau disease

Relative value of computed tomography scanning and venous sampling in establishing the cause of primary hyperaldosteronism.

The purpose of this study was to evaluate the relative merits of the postural stimulation test, adrenal computed tomography (CT) and venous sampling in the differential diagnosis of patients presenting with primary hyperaldosteronism. The records of 20 patients presenting with primary hyperaldosteronism were reviewed retrospectively. There were 15 patients with a unilateral aldosterone-producing adenoma (APA), four patients with idiopathic hyperaldosteronism (IHA) and one patient with primary adrenal hyperplasia (PAH). The postural stimulation test was based on measurements of plasma aldosterone and renin activity at 08.00 h and at noon after 4 h of ambulation. The CT scans of the adrenals were reviewed by a single radiologist. Bilateral venous sampling of adrenal veins was attempted in all patients and blood collected for aldosterone and cortisol assay. Plasma aldosterone concentration increased after 4 h of standing in all cases of hyperplasia but was also demonstrated in 10/15 patients with a surgically-proven APA. If one defines a significant postural rise as being greater than 30%, then 8/15 patients with APA can be considered as being posturally responsive. Computed tomography scanning correctly identified all 15 cases of APA and also classified correctly the remaining five cases of hyperplasia (four cases of IHA and one case of PAH). Venous sampling failed technically in 4/15 cases of APA and in one case of IHA: a total of 5/20 (25%,). A correct diagnosis of APA or IHA was established in all the remaining cases. However, the one case of PAH was treated successfully by adrenalectomy following venous sampling, which suggested a unilateral adrenal lesion: this one result was the only instance where venous sampling altered clinical decision-making. Computed tomography scanning may be used alone to confirm the cause of hyperaldosteronism where postural studies suggest an adrenal adenoma, and such patients may be considered for early surgery. Venous catheterization studies are not necessary routinely. but may still be useful in selected patients, particularly when CT scanning shows no clear lesion

A critical analysis of the value of simultaneous inferior petrosal sinus sampling in Cushing's disease and the occult ectopic adrenocorticotropin syndrome.

The clinical, biochemical, and radiological features of pituitary ACTH-dependent Cushing's syndrome (CS) [Cushing's disease (CD)] are often indistinguishable from those of occult ectopic ACTH-dependent CS (oEAS). We have evaluated, retrospectively, the results of simultaneous bilateral inferior petrosal sinus (IPS) ACTH sampling before and after CRH stimulation in 128 patients with ACTH-dependent CS: 107 patients with CD, 6 with oEAS, 1 with an adrenal adenoma, 1 with a pituitary gangliocytoma, and 1 with Nelson's syndrome; while, in the remaining 12, the source remains unclear. One hundred seven patients received human-sequence CRH (hCRH), and 11 received ovine CRH; another 6 patients underwent stimulation with desmopressin and hCRH, and 4 with desmopressin alone. A successful bilateral IPS catheterization and sampling (IPSCS) rate of 87.5% was obtained only after considerable experience had been gained. Sixty-nine patients with CD underwent successful bilateral IPSCS: the IPS-to-peripheral ratio of plasma ACTH value (IPS/P) rose from 9.5 +/- 1.4 to a maximum ratio of 55.8 +/- 7.5 in 67 patients, after CRH stimulation. The maximum ratio was obtained at 5 min in 60 of the 69 patients with CD; however, all 69 patients obtained a ratio of more than 2, at that time. In contrast, the 6 patients with occult ACTH-secreting neoplasms had a maximal IPS/P ratio of 1.3 +/- 0.16, and this did not change after CRH stimulation. A bilateral IPS/P ratio more than 2, obtained 5 min after CRH stimulation, had a sensitivity of 97% and a specificity of 100% in diagnosing CD. Two patients with proven active CD had an IPS/P ratio of less than 2. After successful bilateral IPSCS, the gradients between the IPS ACTH concentrations [IPS ACTH gradient (IPSG)] of more than 1.4, at 5 min after CRH stimulation, had a sensitivity of 83% in correctly lateralizing the pituitary microadenoma, compared with 72% sensitivity for magnetic resonance imaging (MRI) scanning. Furthermore, when IPSG and MRI findings were contradictory, IPSG was more often correct than MRI scanning. Although oEAS is a relatively uncommon cause of ACTH-dependent hypercortisolism (5.5% in our series), the accurate diagnosis of ACTH-dependent CS and localization of an intrapituitary microadenoma requires bilateral IPSCS with CRH stimulation, provided that the appropriate technical experience is available. hCRH is as effective a secretagogue as ovine CRH, and either may be used. The value of the combination of CRH and desmopressin stimulation requires more detailed investigation