Polycythemia Vera Clinical Trial
Official title:
Incidence of Iron Deficiency in Polycythemia Vera (PV) and Association With Disease Features
Iron deficiency is a known feature of PV, occurs because of accelerated erythropoiesis,
gastrointestinal blood loss and phlebotomy. Incidence and effect of iron deficiency in these
patients is not well characterized. The study will assess the incidence of iron deficiency
at diagnosis and during the course of PV, assess effect of iron deficiency on patient
symptoms and its correlation with disease features.
This is a multicenter, non-interventional, non-randomized, prospective, observational study
in an adult population (patients >18 years old) of patients who have been diagnosed with PV
and are being followed in either community or academic medical centers in Israel.
Background:
Within intestinal epithelial cells, some of the imported iron is incorporated into ferritin
and other storage forms. A fraction of the iron taken up from the intestinal lumen passes
through the cell, and is exported across the basolateral membrane to enter the body.
Ferroportin, a metal ion transporter, serves as the basolateral iron exporter. Hepcidin
regulates basolateral iron export by binding to ferroportin to trigger its internalization
and lysosomal degradation. Each day, normal adults need 25 mg of iron to support hemoglobin
production in maturing erythrocytes. This amount is much greater than the iron absorbed
daily through the intestine. Obviously, iron needed for erythropoiesis must be acquired from
supplies already existing in the body. The primary source of plasma iron is the
reticuloendothelial macrophage system, which recovers iron from senescent and damaged
erythrocytes. Other significant site of iron exchange is the liver.
Dietary iron absorption is enhanced in response to insufficient iron stores, increased
erythropoietic demand or hypoxia. It is diminished in response to iron surfeit and
inflammation. Based on these observations, four different "regulators" have been defined
functionally: 1) The stores regulator modulates absorption several fold, increasing it in
iron deficiency and decreasing it in iron overload. 2) The erythroid regulator is more
potent—it can increase iron absorption 6- to 10-fold when erythropoiesis becomes iron
-restricted, result either from iron deficiency or from accelerated production of erythroid
precursors. 3) The hypoxia regulator mediates an increase in iron absorption in response to
hypoxia, to allow for production of hemoproteins that bind and carry oxygen. 4) An
inflammatory regulator also exists, which acts to decrease iron absorption in response to
inflammation. All of these regulators act through a common, humoral effector that
coordinates intestinal iron absorption and macrophage iron recycling. Hepcidin plays a major
role in iron metabolism. It is produced in the liver, cleaved from a larger precursor
molecule and secreted into the plasma. Circulating hepcidin attaches to ferroportin
expressed on enterocytes and macrophages, causing ferroportin to be internalized into the
cell and degraded in lysosomes. Hepcidin is induced in response to iron overload and
inflammation. It is turned off in response to iron deficiency , ineffective erythropoiesis
and hypoxia.
Polycythemia vera (PV) is one of the myeloproliferative neoplasms (MPNs) and is
characterized by marrow hyperplasia with an increased number of erythrocytes, leukocytes and
platelets in peripheral blood. Several studies have shown that iron deficiency is common in
PV patients and can significantly influence the quality of their life. These complications
are a result of expansive erythropoiesis, in addition to phlebotomy and/or gastrointestinal
bleedings. The role of JAK2V617F in pathogenesis of iron deficiency in PV is also very
intriguing. Kinase JAK2 is involved in signal transduction via the erythropoietin receptor.
EPO is one of the hepcidin synthesis regulators. Some of the data has confirmed that JAK2
mutation may be involved in the regulation of the iron status in myeloproliferative
disorders.
There are several reports in the literature on thrombotic complications in iron-deficient
adults. Secondary thrombocytosis has been implicated in many cases.
In addition to the increased thrombotic risk associated with high platelet count, the
decrease in antioxidant defense in iron deficiency may cause increased oxidant stress, which
in turn may result in a tendency toward platelet aggregation. The abnormal platelet count
and function observed in iron deficiency anemia could act synergistically to promote
thrombus formation. Iron deficiency may contribute to a hypercoagulable state by affecting
blood flow patterns within the vessels because of reduced deformability and increased
viscosity of microcytic red blood cell.
Purpose:
Incidence and effect of iron deficiency in patients with PV is not well characterized. The
study will assess the incidence of iron deficiency at diagnosis and during the course of PV,
assess effect of iron deficiency on patient symptoms and its correlation with disease
features.
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