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Clinical Trial Summary

Cardiac amyloidosis describes a process by which abnormally folded proteins infiltrate the heart tissue. Given the insidious nature of this disease process, diagnosis is often too late for a meaningful intervention. Advances in the treatment of the amyloidoses have improved outcomes for patients with these conditions. The focus of this study is to identify the involvement of the heart, most closely associated with mortality, so that aggressive management can be instituted improving prognosis.


Clinical Trial Description

RESEARCH PROTOCOL

Hypothesis:

The presence of amyloid protein in the myocardium changes its function and tissue characteristics. These changes are responsible for the poor prognosis of patients with cardiac amyloidosis. Cardiac magnetic resonance imaging (CMR) offers a novel, non-invasive approach to identify cardiac involvement that may impact patient management. This study will include the prospective validation of CMR parameters qualified as being abnormal in the retrospective study (study ID 2012-3315) and the current literature. The myocardium/blood pool inversion time null point ratio (Myo/BlP TI0 ratio), has been qualified as being significantly different when compared to controls in the retrospective study.

Specific Aims:

1. Validate the diagnostic accuracy of CMR parameters in a prospective manner for cardiac amyloidosis patients.

2. CMR parameters, including the Myo/BlP TI0 ratio, will be compared to serum biomarkers (TroponinT, NT-proBNP, serum lambda/kappa free light chain concentration), established to have prognostic value in cardiac amyloidosis. Subjects will be followed via death registry and/or medical records to compare the prognostic value of the CMR parameter with the biomarkers.

3. CMR parameters will be used to assess for the presence of early cardiac involvement in amyloidosis patients without clinically apparent cardiac involvement (as determined by symptoms, biomarkers and/or cardiac imaging).

4. CMR will be used to follow patients undergoing treatment, when available, to determine whether CMR parameters consistent with the presence of cardiac amyloidosis, change during treatment.

Background and Significance:

Matthias Schleiden, a German botanist and co-creator of the cell theory, used the term amyloid in 1834 to characterize the waxy starch in plants. Today, amyloid is used to describe any of a number of small proteins which when aggregated lead to insoluble fibrillar deposits. Many mechanisms of protein dysfunction contribute to amyloidogenesis, including "non-physiologic proteolysis, defective physiologic proteolysis, mutations involving changes in thermodynamic or kinetic properties, and pathways that are yet to be defined". Amyloid deposits are identified on the basis of their apple-green birefringence under a polarized light microscope after staining with Congo red. They can also be identified based on the presence of rigid, non-branching fibrils using electron microscopy. Amyloidosis describes the infiltration of organs by these insoluble deposits. In humans, about 27 different unrelated proteins are known to form amyloid fibrils in vivo. The organs involved and clinical presentations are dependent on the precursor protein. A small number of the amyloidoses can have cardiac involvement with a significant impact on mortality. The clinically most significant cardiac amyloidoses include immunoglobulin light chain amyloidosis (AL) and the transthyretin amyloidoses (ATTR); ATTR being either hereditary secondary to mutations in the transthyretin gene or acquired secondary to wild type transthyretin protein.

AL amyloidosis, the most common type of systemic amyloidosis, is associated with plasma cell dyscrasias. In AL amyloidosis, fifty percent of affected patients will have cardiac involvement. Despite the potential for amyloid deposition in multiple organs, cardiac involvement continues to dictate the poorest prognosis. Once congestive heart failure develops in a patient with AL amyloidosis, survival is less than 6 months if untreated. Therefore, patients with AL amyloidosis are screened, by assessing serum troponins and brain natriuretic peptides, to determine whether cardiac involvement is present. Patients with ATTR amyloidosis typically has a more insidious onset in comparison. ATTR amyloidosis also responds better to traditional congestive heart failure management. However, neither AL nor the ATTR amyloidoses are managed like traditional heart failure making appropriate diagnosis critical for best care. Furthermore, early diagnosis of cardiac involvement may improve outcomes but requires heightened suspicion and a systematic clinical approach to evaluation [3].

In cardiac amyloidosis, there can be evidence of disease on routine testing. Restrictive physiology by echocardiography, low EKG voltage as well as additional EKG abnormalities are often identified in advanced cardiac amyloidosis. Routine nuclear cardiac imaging has not proven to be helpful in diagnosis, although 123I-MIBG does appear to demonstrate co-localization of denervation with amyloid deposition. Unfortunately, no routine cardiac testing is specific for cardiac amyloidosis. Therefore, in the absence of high clinical suspicion for cardiac amyloidosis, the appropriate diagnosis will often be missed.

Endomyocardial biopsy remains the gold standard for making the diagnosis of cardiac involvement. However, given the invasive nature of endomyocardial biopsy and associated risks (including death), the diagnosis of cardiac amyloidosis is usually made by non-invasive means; this diagnosis being supported by a non-cardiac biopsy demonstrating amyloid deposits. The most frequently biopsied site is the abdominal fat pad, usually positive in patients with AL amyloidosis. However, ATTR amyloidosis is not reliably identified with fat pad biopsy. Therefore, a negative fat pad biopsy requires further work up including endomyocardial biopsy with associated immunostaining and genetic testing for transthyretin mutations. Supporting the diagnosis of cardiac amyloidosis by noninvasive techniques such as EKG, echocardiography and serum amyloid component scintigraphy has been shown to have significant limitations. A novel non-invasive approach is required to ensure accurate diagnosis. Given the limitations of previously used non-invasive techniques, there has been interest over the last decade in using cardiovascular magnetic resonance (CMR) imaging in the diagnosis of cardiac amyloidosis.

The utility of CMR in evaluating patients with cardiac amyloidosis was first proposed in the 1990s. However, evaluation was limited to the assessment of myocardial morphology and function. It was not until the turn of the century that the powerful diagnostic potential of delayed gadolinium enhancement (DGE) was realized. The first utility of DGE was in the evaluation of myocardial viability in patients with coronary artery disease. It quickly became apparent that DGE could also be used to evaluate patients with non-ischemic cardiomyopathies. The characterization of cardiac amyloidosis with DGE was first described as global sub-endocardial enhancement. Abnormal T1 transmyocardial maps were used to both describe the abnormality and to assist in the determination of prognosis. However, these studies were limited by inclusion of only patients with biopsy-proven amyloidosis who also met the echocardiographic criteria for restrictive physiology, common to advanced cardiac amyloidosis. More recent work precluding the use of echocardiographic diagnosis supported the concept that the inability to null the myocardium relative to the blood pool may be an early sign of cardiac amyloidosis. In addition, to the DGE data, studies have utilized T1 and T2 weighted imaging to identify abnormal extracellular volume (ECV) and myocardial edema in the cardiac amyloidosis population.

It has been the culmination of these findings, in addition to our own experience studying cardiac amyloidosis that led to the hypothesis that the presence of amyloid protein, known to increase the ECV, may also change the inversion time curves of both the blood pool and the myocardium. These features, as well as abnormal functional parameters, will help detect cardiac amyloidosis earlier than would otherwise be possible by morphologic assessment. The possibility of diagnosing sub-clinical disease has implications for screening patients with known amyloidosis for early cardiac involvement. Also, CMR parameters may be useful in assessing response to treatment of the plasma cell dyscrasias, such as cardiac amyloidosis, that may be complicated by heart failure and ventricular tachycardia. Lastly, the relationship of the MRI findings to cardiac biomarkers has yet to be described and will be assessed in this study.

Preliminary Data:

The investigators have observed a significant difference between the Myo/BlP TI0 ratio in patients with cardiac amyloidosis when compared with controls both with preserved LV function (CTL) and non-amyloid cardiomyopathies (CTL-CMP). The Myo/BlP TI0 ratio of the CA group is close to 1 to 1 (0.95 +/- 0.16) leading to poor myocardium and blood pool contrast in the corresponding delayed enhancement images acquired following the TI scout (Figure 7). The Myo/BlP TI0 ratio provides a quantitative method to support the diagnosis of cardiac amyloidosis in patients presenting with cardiac symptoms.

Estimated Period of Time to Completion:

Estimated time to completion of aim 1, 2 and 4 will depend on power calculations following the acquisition of pilot prospective data. The estimated timing of completion of aim 3 will be 12-18 months from the start of data acquisition. ;


Study Design


Related Conditions & MeSH terms


NCT number NCT02462213
Study type Observational
Source University of Cincinnati
Contact
Status Withdrawn
Phase N/A
Start date October 2013
Completion date December 2017

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