Clinical Trial Details
— Status: Not yet recruiting
Administrative data
| NCT number |
NCT06175858 |
| Other study ID # |
cardiac amyloidosis |
| Secondary ID |
|
| Status |
Not yet recruiting |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
January 2024 |
| Est. completion date |
May 2027 |
Study information
| Verified date |
December 2023 |
| Source |
Assiut University |
| Contact |
Alsayed ahmed |
| Phone |
01127450433 |
| Email |
sayedkelany20[@]gmail.com |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
The study aims to test and compare the diagnostic yield of different diagnostic modalities
(speckle tracking echocardiography, CMR, serum and urine protein analysis and bone tracer
scintigraphy) in the detection of cardiac amyloidosis among patients with "red flags"
suspecting cardiac amyloidosis.
Description:
Cardiac amyloidosis (CA) is a condition that can be caused by rare genetic variants in the
hereditary forms or because of acquired conditions. It is one of the serious and progressive
infiltrative disease that is caused by the deposition of amyloid fibrils at the cardiac level
.
Cardiac amyloidosis causes restrictive cardiomyopathy, and this is caused by extracellular
deposition of proteins in the myocardium. The proteins have an unstable structure that causes
them to misfold, aggregate, and deposit as amyloid fibrils .
According to the nature of the infiltrating protein, cardiac amyloidosis has two main
subtypes, immunoglobulin light chain cardiac amyloidosis (AL-CA), and transthyretin cardiac
amyloidosis (ATTR-CA) which is further subdivided according to the presence or absence of a
mutation in the transthyretin gene into wild-type (ATTRwt-CA) and variant (ATTRv-CA) .
Despite of being one of the most serious, fetal diseases, and a considerable cause of heart
failure with preserved ejection fraction (HFpEF), cardiac amyloidosis is still significantly
underdiagnosed, this may be due to its varied presentations and lack of awareness about the
nature of the disease. Awareness of "red flags" suggestive of amyloidosis can enhance one's
index of appropriate clinical suspicion and enable earlier diagnosis of CA .
Diagnosis of CA:
Diagnosis and classification of CA needs high index of clinical suspicion and awareness of
clinical clues suggestive of CA. This ranges from ECG, echocardiography, speckle tracking,
laboratory investigations, bone scan scintigraphy and cardiac MRI.
ECG:
Although ECG may be normal even at advanced stages of CA, it can provide clues for amyloid
infiltration and further support the diagnosis in conjunction with imaging findings. The
typical finding is normal or low QRS voltage (<1 mV in the precordial and <0.5 mV in the
extremity leads) in patients with LV hypertrophy on echocardiography. This is more common in
AL-CA (45%) but less frequent in ATTR-CA (23-31%) .
Other features include pseudo-infarct pattern with Q waves or slow R-wave progression in the
precordial leads, atrioventricular block or bundle branch block. Atrial fibrillation is the
most common arrhythmia with a high relapse rate .
Echocardiography:
1. Conventional Measures and Diastolic Function Transthoracic echocardiography is usually
the initial imaging technique for evaluating patients with suspected cardiac
amyloidosis. Typical echocardiographic findings are increased left ventricular (LV) wall
thickness over 12 mm, accompanied by additional thickening of the right ventricle (RV),
valves, and interatrial septum, and generally small pericardial effusion .
Furthermore, bi-atrial dilatation is frequently observed in severe diastolic
dysfunction. The characteristic speckled appearance of the myocardium, on the other
hand, referred to as "granular sparkling," has been described in patients with cardiac
amyloidosis and previously deemed as a key factor in establishing the diagnosis .
However, granular sparkling can also be present in other causes of LV hypertrophy,
yielding lower sensitivity for identifying cardiac amyloidosis than previously
anticipated. In addition, tissue harmonic imaging and image processing techniques may
alter the myocardial echogenicity and, thus, impair the diagnostic value of this feature
.
Generally, LV diastolic abnormalities occur already in the early stages of cardiac
amyloidosis. In contrast, LV ejection fraction usually remains normal or mildly reduced
until the late stages of the disease, despite diminished longitudinal deformation of the
myocardium. Despite preserved ejection fraction, cardiac output is low due to decreased
ventricular volumes .
In this regard, myocardial contraction fraction, the ratio of (LV) stroke volume to
myocardial volume measured by M-mode echocardiography, was predictive of mortality in
patients with ATTRv, ATTRwt, and AL amyloidosis .
2. The Role of Echocardiographic Myocardial Deformation (Strain) Changes in the myocardium
in dimensions and shape during contraction and relaxation can be characterized by
assessing myocardial "strain." Strain is a measure of regional or global deformation,
which originates from physics and can be applied to the heart to measure regional
shortening, thickening, and lengthening of the myocardium. Strain can be quantitatively
assessed by echocardiography using speckle tracking imaging and has demonstrated a
characteristic pattern with markedly reduced strain in mid and basal and relatively
preserved strain in apical segments. This pattern is referred to as "apical sparing" and
is well suited for differentiating such patients from other causes of LV hypertrophy
(13). The apical sparing pattern is easily recognizable on polar myocardial strain maps
and is observed in patients with ATTR and AL cardiac amyloidosis.
In addition, in several previous clinical studies, the myocardial strain was shown to bear
prognostic implications in amyloidosis, exhibiting incremental value over clinical and
biochemical markers for the risk stratification of patients with AL amyloidosis .
Laboratory testing:
As no single parameter exists for diagnosing ATTR-CA, the goal of laboratory testing in
patients with suspected CA is primarily to search for markers of plasma cell disease causing
AL-amyloidosis. These include elevated serum free light chain immunoglobulins, pathologic to
free light chain ratio and monoclonal gammopathy in serum and urine immunofixation with
reported sensitivity of >95% for the detection of AL amyloidosis .
Urine protein analysis can also be helpful in diagnosis cardiac amyloidosis and
differentiating the type.
Bone Tracer Scintigraphy:
Cardiac uptake of 99mTc-phosphate derivatives was first demonstrated in the 1980s as an
accidental finding in patients with ATTR- CA undergoing scintigraphy for metastatic bone
disease. In 2005 a small study demonstrated the diagnostic value of
99mTc-3,3-diphosphono-1,2-propanodicarboxylic acid (99mTc-DPD) for ATTR-CA .
Since then, several studies reported on the high sensitivity of bone-tracer scintigraphy for
ATTR-CA with only mild or absent tracer uptake in AL-CA, attributed possibly to higher
calcium con- tent in ATTR amyloid deposits .
These results were recently validated in a large-scale multicenter trial, which showed high
diagnostic accuracy of 99mTc-phosphate scintigraphy for non-invasive detection of ATTR-CA .
Qualitative visual Perugini scale relate heart uptake as compared with rib bone uptake and
include grade 0 = no uptake, grade 1 = mild uptake, less than rib (less than bone for
99mTc-DPD), grade 2 = moderate uptake, equal to rib, grade 3 = severe uptake, greater than
rib.
In summary, a scan demonstrating grade 2 or 3 uptake according to the visual Perugini scale
combined with negative serum and urine analysis for elevated free light chains and monoclonal
gammopathy demonstrated 99% sensitivity, 100% positive predictive value and 100% specificity
for ATTR-CA .
Cardiac Magnetic Resonance (CMR):
1. Conventional Cine Measures by CMR:
CMR allows for non-invasive imaging of cardiac structures with high spatial resolution
and intrinsic blood-to-tissue contrast. The versatility of CMR can provide the
assessment of myocardial function, perfusion, tissue characterization by late gadolinium
enhancement (LGE) and mapping techniques, and, if required, myocardial deformation using
"strain" analyses within a single examination, independent of the patients' acoustic
windows and without radiation exposure .
Morphological and functional alterations are comparable with echocardiography findings.
In addition, CMR studies highlighted differences in asymmetrical septal hypertrophy in
ATTR amyloidosis, mimicking hypertrophic cardiomyopathy versus concentric hypertrophy
seen in most patients with AL amyloidosis .
2. Late Gadolinium Enhancement:
Gadolinium is an extracellular contrast agent. Therefore, gadolinium distributes
preferentially in areas of increased extracellular volume (ECV), as in diseased
myocardium with an expanded extracellular space in patients with cardiac amyloidosis. In
contrast, the contrast agent rapidly washes out in healthy myocardium. LGE images are
typically acquired approximately 10 min after contrast agent administration. LGE allows
for visual and if required, quantitative assessment of the myocardial amyloid burden,
albeit challenging in diffuse global LGE with progressed disease cases. Several studies
previously demonstrated the presence of LGE in patients with cardiac amyloidosis .
The sensitivity and specificity of LGE versus endomyocardial biopsy for diagnosing
cardiac amyloidosis were reported to be 86% and 92%, respectively, based on a recent
meta-analysis .
3. Native T1 Mapping and Extracellular Volume (ECV):
Native T1 Measures of the myocardial T1 relaxation with non-contrast T1 mapping sequences
have been used to detect and quantify interstitial expansion due to fibrosis . In cardiac
amyloidosis, native T1 mapping exhibited significantly higher values in patients than in
control subjects. In the same direction, T1 elevations were noted in AL and ATTR amyloidosis
patients, allowing for differentiation between both subtypes of amyloidosis versus
hypertrophic cardiomyopathy with high accuracy . In addition, native T1 values were shown to
be related to functional echocardiographic markers of systolic and diastolic LV function and
significantly increased even in asymptomatic amyloidosis patients, thus being potentially
more sensitive than LGE .
Extracellular Volume (ECV) By measuring the T1 value of the myocardium before and after
gadolinium administration, the myocardial ECV can be quantified. This parameter reflects the
fraction of myocardium composed by the extracellular space, where the amyloid deposits
accumulate in patients with cardiac amyloidosis. ECV requires administering gadolinium-based
contrast agents but is less susceptible to technical issues than the pulse sequences used for
native T1 mapping . Like native T1, ECV has been extensively validated in cardiac amyloidosis
, including studies where ECV was serially studied during treatment with novel pharmacologic
agents in AL and ATTR amyloidosis. Due to its high reproducibility and quantitative nature,
the use of ECV was proposed for serial studies, monitoring the response to therapies in
patients with cardiac amyloidosis. In addition, ECV has been validated against histology,
exhibiting a close correlation to histologic amyloid burden and was independently associated
with patients' outcomes .
In ATTR amyloidosis, ECV was, in contrast to native T1 values, independently associated with
mortality after adjustment for age, biochemical, functional markers, and LGE. This highlights
the robustness of this marker which was recently confirmed in a meta-analysis by a systematic
comparison of ECV versus native T1 in AL and ATTR amyloidosis patient cohorts. Summarizing
the relevance of native T1 and ECV, both markers bear diagnostic solid and prognostic
implications and need to be considered together with clinical, laboratory, and other imaging
parameters during the diagnostic work-up of patients with suspected cardiac amyloidosis.
