Determination of urinary iodine by inductively coupled plasma mass spectrometry.

BACKGROUND: Mild iodine deficiency is endemic in many countries of Europe including Belgium. Fast, accurate and specific methods for quantification of urinary iodine are needed. We describe in this report a specific ICP-MS method for the quantification of urinary iodine. METHOD: Samples and iodate calibrators were diluted 20 times into aqueous solution containing triton X-100, 1.5% HCl and (103)Rh as an internal standard. Prior digestion or oxidation was not necessary. Results were compared with those obtained by Sandell-Kolthoff (S-K) spectrophotometric method. RESULTS: Comparison of both methods showed good agreement. The Passing-Bablok regression between both methods was ICP-MS=0.986 (S-K)-7.51. The Bland-Altman difference plot showed a small but significant mean difference of -13.3 microg/L for ICP-MS. The between-day coefficient of variation (CV) was 13% at 89 microg/L. Limit of detection was 4 microg/L and limit of quantification was 20 microg/L. No carryover effect has been observed on series containing up to 50 samples. CONCLUSION: The ICP-MS method described here is fast, accurate and specific for the quantification of urinary iodine. Compared to the S-K method the urinary iodine concentrations measured by the ICP-MS method were slightly, but significantly lower. Consequently, the results of studies using S-K method should be compared with caution with those using the ICP-MS method.

Sphingolipid-cholesterol domains (lipid rafts) in normal human and dog thyroid follicular cells are not involved in thyrotropin receptor signaling.

Partition of signaling molecules in sphingolipid-cholesterol-enriched membrane domains, among which are the caveolae, may contribute to signal transduction efficiency. In normal thyroid, nothing is known about a putative TSH/cAMP cascade compartmentation in caveolae or other sphingolipid-cholesterol-enriched membrane domains. In this study we show for the first time that caveolae are present in the apical membrane of dog and human thyrocytes: caveolin-1 mRNA presence is demonstrated by Northern blotting in primary cultures and that of the caveolin-1 protein by immunohistochemistry performed on human thyroid tissue. The TSH receptor located in the basal membrane can therefore not be located in caveolae. We demonstrate for the first time by biochemical methods the existence of sphingolipid-cholesterol-enriched domains in human and dog thyroid follicular cells that contain caveolin, flotillin-2, and the insulin receptor. We assessed a possible sphingolipid-cholesterol-enriched domains compartmentation of the TSH receptor and the alpha- subunit of the heterotrimeric G(s) and G(q) proteins using two approaches: Western blotting on detergent-resistant membranes isolated from thyrocytes in primary cultures and the influence of 10 mm methyl-beta-cyclodextrin, a cholesterol chelator, on basal and stimulated cAMP accumulation in intact thyrocytes. The results from both types of experiments strongly suggest that the TSH/cAMP cascade in thyroid cells is not associated with sphingolipid-cholesterol-enriched membrane domains.

[The medical chemistry department]. / Le Service de Chimie Médicale.

The laboratory of clinical chemistry performs more than 300 different tests in biochemistry, hormone and tumor markers analysis, therapeutic drug monitoring and toxicology. For the most basic tests it has followed the trend of clinical chemistry towards automation and since 2001 the heart of the laboratory is a modular automated system (MODULAR) including a preanalytical platform, unique in Belgium. For more sophisticated tests, the most recent techniques have been implemented, in particular capillary electrophoresis and ICP-MS ("inductively coupled plasma-mass spectrometry). Since 1994, the laboratory has become a reference center in the field of erythrocyte hereditary diseases, combining screening, diagnosis and research. The other research themes are the physiopathology of first trimester pregnancy and the P2Y receptors of extracellular nucleotides.

Biosynthesis and metabolism of 2-iodohexadecanal in cultured dog thyroid cells.

2-Iodohexadecanal (2-IHDA) is a major thyroid iodolipid. It mimics the main regulatory effects of iodide on thyroid metabolism: inhibition of H2O2 production and of adenylyl cyclase. The biosynthesis of 2-IHDA and its metabolism have been investigated in cultured dog thyroid cells maintained in a differentiated state by forskolin. Incubation of these cells with [9,10-3H]hexadecan-1-ol or [9,10-3H]palmitic acid labeled several phospholipids, but [9, 10-3H]hexadecan-1-ol was selectively incorporated into plasmenylethanolamine. In the presence of an exogenous H2O2 generating system (glucose oxidase), iodide induced the production of [9,10-3H]2-IHDA from [9,10-3H]hexadecan-1-ol-labeled cells but not from [9,10-3H]palmitic acid-labeled cells. 2-IHDA was also generated during the lactoperoxidase-catalyzed iodination of brain and heart plasmalogens, and of ethyl hexadec-1-enyl ether, a synthetic vinyl ether-containing compound. Taken together, these results show that thyroid 2-IHDA is derived from plasmenylethanolamine via an attack of reactive iodine on the vinyl ether group. 2-Iodohexadecan-1-ol (2-IHDO) was also detected in these studies; it was formed later than 2-IHDA, and thyroid cells converted exogenous 2-IHDA into 2-IHDO in a time-dependent way. The ratio of 2-IHDO/2-IHDA increased with H2O2 production and decreased as a function of iodide concentration. An aldehyde-reducing activity was detected in subcellular fractions of the horse thyroid. No formation of 2-iodohexadecanoic acid could be detected. Reduction into the biologically inactive 2-IHDO is thus a major metabolic pathway of 2-IHDA in dog thyrocytes.