Iron Overload Clinical Trial
Official title:
Massive Iron Deposit Assessment
| Verified date | April 2019 |
| Source | St. Jude Children's Research Hospital |
| Contact | n/a |
| Is FDA regulated | No |
| Health authority | |
| Study type | Interventional |
Iron overload is a severe complication of multiple blood transfusions. As the body has no
physiologic mechanism for clearing iron, repeated transfusions cause iron accumulation in
organs and lead to iron toxicity. Accurate assessment of iron overload is paramount to
quantify excessive iron accumulation and to monitor response to iron chelation therapy.
Magnetic resonance imaging (MRI) methods have been used to noninvasively measure hepatic iron
concentration (HIC). Although MRI-based measurements of transverse relaxation rates (R2 and
R2*) accurately predict biopsy-proven HICs below 15 mg Fe/g, previous studies have shown that
their precision is limited for HICs above 15 mg Fe/g and inaccurate above 25 mg Fe/g. Current
R2* gradient-echo (GRE) MR techniques fail occasionally for very high iron overloads (HIC ~
15-25 mg Fe/g) and always for massive iron overloads (HIC > 25 mg Fe/g) because R2* is so
high that the MR signal decays before it can be measured accurately.
Overall accrual: 200 patients
Purpose: To determine if a new MRI (UTE) can measure the amount of iron in the liver of
people with large amounts of iron and compare the results with the same patient's liver bx.
Estimated patient accrual is 150. It is estimated that 41 of these patients will have
clinical indication for liver biopsy.
| Status | Completed |
| Enrollment | 142 |
| Est. completion date | February 28, 2018 |
| Est. primary completion date | February 28, 2018 |
| Accepts healthy volunteers | No |
| Gender | All |
| Age group | N/A and older |
| Eligibility |
Inclusion Criteria - History of 12 or more lifetime erythrocyte transfusions, AND - Need for liver iron content assessment (by MRI or liver biopsy) Exclusion Criteria - Presence of certain MR-unsafe foreign material in the body, or other conditions that make the research participant ineligible for an MRI scan per St. Jude policies. - Any condition or chronic illness that in the opinion of the PIs makes participation on study ill-advised. |
| Country | Name | City | State |
|---|---|---|---|
| United States | St. Jude Children's Research Hospital | Memphis | Tennessee |
| Lead Sponsor | Collaborator |
|---|---|
| St. Jude Children's Research Hospital | National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK), Regional One Health |
United States,
| Type | Measure | Description | Time frame | Safety issue |
|---|---|---|---|---|
| Primary | Hepatic Iron Content in the Liver Using Liver Biopsy | Hepatic iron content in the liver using liver biopsy | up to 30 days after MRI | |
| Primary | MRI-derived R2* Values Using 1.5T UTE Technique | Hepatic iron content of the liver using MRI-derived 1.5T R2*-UTE measurement, with results in Hz. R2* is a measure obtained with MRI, i.e., MRI R2*. It is measured in hertz (Hz). In lay terms, the MRI machine picks up a signal back from the tissue during the process of scanning the tissues. With every "picture taken", this signal is strong in the beginning and then wanes off. R2* reflects how fast the signal wanes off. If there is too much iron in the tissue, the signal disappears faster, making the T2* value low. T2* is the reciprocal of R2* (R2*= 1/T2*). So, if the signal drops fast, the T2* is low and the R2* is high. In this study, we are measuring the R2* value. The higher the R2*, the more iron in the liver tissue. We can compare the R2* value with that of a liver biopsy to then use the R2* value to tell us how much iron is in the liver without having to biopsy the liver. | Up to 30 days after MRI | |
| Secondary | MRI-derived R2* Using 1.5T GRE Technique | MRI-derived R2* Using 1.5T GRE Technique in Hz. R2* is a measure obtained with MRI, i.e., MRI R2*. It is measured in hertz (Hz). In lay terms, the MRI machine picks up a signal back from the tissue during the process of scanning the tissues. With every "picture taken", this signal is strong in the beginning and then wanes off. R2* reflects how fast the signal wanes off. If there is too much iron in the tissue, the signal disappears faster, making the T2* value low. T2* is the reciprocal of R2* (R2*= 1/T2*). So, if the signal drops fast, the T2* is low and the R2* is high. In this study, we are measuring the R2* value. The higher the R2*, the more iron in the liver tissue. We can compare the R2* value with that of a liver biopsy to then use the R2* value to tell us how much iron is in the liver without having to biopsy the liver. | Up to 30 days after MRI | |
| Secondary | MRI Derived R2* Using 1.5T UTE Technique | MRI-derived R2* value using 1.5T R2*-UTE in Hz. R2* is a measure obtained with MRI, i.e., MRI R2*. It is measured in hertz (Hz). In lay terms, the MRI machine picks up a signal back from the tissue during the process of scanning the tissues. With every "picture taken", this signal is strong in the beginning and then wanes off. R2* reflects how fast the signal wanes off. If there is too much iron in the tissue, the signal disappears faster, making the T2* value low. T2* is the reciprocal of R2* (R2*= 1/T2*). So, if the signal drops fast, the T2* is low and the R2* is high. In this study, we are measuring the R2* value. The higher the R2*, the more iron in the liver tissue. We can compare the R2* value with that of a liver biopsy to then use the R2* value to tell us how much iron is in the liver without having to biopsy the liver. | up to 30 days after MRI | |
| Secondary | R2* Using 1.5T UTE Technique for Patients With Serum Iron and Transferrin Saturation Measurements | MRI-derived R2* value using 1.5T R2*-UTE in Hz for patients who have had serum iron and transferrin saturation measurements. R2* is a measure obtained with MRI, i.e., MRI R2*. It is measured in hertz (Hz). In lay terms, the MRI machine picks up a signal back from the tissue during the process of scanning the tissues. With every "picture taken", this signal is strong in the beginning and then wanes off. R2* reflects how fast the signal wanes off. If there is too much iron in the tissue, the signal disappears faster, making the T2* value low. T2* is the reciprocal of R2* (R2*= 1/T2*). So, if the signal drops fast, the T2* is low and the R2* is high. In this study, we are measuring the R2* value. The higher the R2*, the more iron in the liver tissue. We can compare the R2* value with that of a liver biopsy to then use the R2* value to tell us how much iron is in the liver without having to biopsy the liver. | Up to 30 days after MRI | |
| Secondary | Serum Iron Measurements Compared With 1.5T R2* UTE | Serum iron measurements from eligible patients had 1.5T R2*-UTE and serum iron and transferrin saturation measurements. | Up to 30 days after MRI | |
| Secondary | Transferrin Saturation Measurements | Iron Transferrin Saturation in % measurements Transferrin Saturation measurements from eligible patients had 1.5T R2*-UTE and serum iron and transferrin saturation measurements. | Up to 30 days after MRI |
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