Talk:Hemochromatosis

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Imported text from Wikipedia. Now in process to revert it to CZ:Live status. Thomas Simmons 10:17, 19 March, 2007 (EPT)

We must pick one version for the title; presumably, the one in more common usage by native English-speaking scientists. --Larry Sanger 18:58, 18 March 2007 (CDT)

Right. How do we do that? Thomas Simmons 12:02, 19 March, 2007 (EPT)

Substantive changes include additional information and sources in the introduction, additional information in the Signs and Symptoms section and deletion of two subsections without sources from

• Pathophysiology

• Crypt cell hypothesis

The sensor pathway inside the enterocyte is disrupted due to the genetic errors. The enterocyte in the crypt must sense the amount of circulating iron. Depending on this information, the cell can regulate the quantity of receptors and channel proteins for iron. If there is little iron, the cell will express many of these proteins. If there is a lot, the cell will turn off the expression of this transporters.

In haemochromatosis, the cell is constantly fooled into thinking there is iron depletion. As a consequence, it overexpresses the necessary channel proteins, this leading to a massive, and unnecessary iron absorption.

These proteins are named DMT-1 (divalent metal transporter), for the luminal side of the cell, and ferroportin, the only known cellular iron exporter, for the basal side of the cell.

• Hepcidin-ferroportin axis

Recently, a new unifying theory for the pathogenesis of hereditary hemochromatosis has been proposed that focuses on the hepcidin-ferroportin regulatory axis. Inappropriately low levels of hepcidin, the iron regulatory hormone, can account for the clinical phenotype of hereditary hemochromatosis. In this view, low levels of circulating hepcidin result in higher levels of ferroportin expression in intestinal epithelial cells and reticuloendothelial macrophages. As a result, this causes increased levels of serum iron, first biochemically detected as increasing transferrin saturation. HFE, hemojuvelin, BMP's and TFR2 are implicated in regulating hepcidin expression. Higher serum iron levels lead to progressive iron loading in tissues.

These may be included later but need rewriting and sources.

I may be going out on a limb here but if these are three or more substantive changes then hopefull this will qualify as CZ:Live. Will continue to work on this. Thomas Simmons 12:02, 19 March, 2007 (EPT)