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| ID | Type | Description | Link |
|---|---|---|---|
| 1R01HL130563-01A1 | U.S. NIH Grant/Contract | View source |
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| Name | Class |
|---|---|
| National Institutes of Health (NIH) | NIH |
| National Heart, Lung, and Blood Institute (NHLBI) | NIH |
| American Heart Association | OTHER |
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Cardiac amyloidosis is a major cause of early treatment-related death and poor overall survival in individuals with systemic light chain amyloidosis. This project will develop a novel approach to visualize cardiac amyloid deposits using advanced imaging methods. The long-term goal of this work is to identify the mechanisms of cardiac dysfunction, in order to guide the development of novel life-saving treatments.
Primary light chain amyloidosis (AL) is the most common systemic amyloidosis, resulting from a plasma cell dyscrasia, a hematological malignancy. It causes a restrictive cardiomyopathy (AL-CMP) in over 70% of individuals. AL-CMP is as lethal as stage 4 lung cancer and more lethal than any other form of restrictive heart disease; if untreated, the mortality rate is 50% within 18 months. Moreover, myocardial dysfunction, the hallmark of AL-CMP, significantly increases early treatment related mortality, predominantly cardiovascular death, and is a powerful predictor of poor long-term survival. Two potentially treatable mechanisms underlie myocardial dysfunction-mechanical effects of amyloid and toxic effects from circulating light chain/ amyloid interactions-and predispose to heart failure, arrhythmias, and sudden death in individuals with AL-CMP. Until now, efforts to determine the mechanisms of AL-CMP have been hampered by a lack of animal models and the limitations of noninvasive techniques to directly image myocardial amyloid. A recent breakthrough, 18F-florbetapir PET/CT, has provided for the first time specific and quantitative imaging of myocardial amyloid including toxic amyloid protofibrils. Furthermore, we propose to investigate three pre-clinically proven pathways of light chain toxicity in humans-myocardial oxidative metabolism, oxidative stress, and coronary microvascular function. Our central hypotheses are that myocardial 18F-florbetapir retention is a biomarker for aggressiveness of AL-CMP and that effective chemotherapy will, by reducing circulating light chains, decrease aggressiveness of AL-CMP and improve oxidative stress, myocardial oxidative metabolism, microvascular function and contractile function, prior to an improvement in myocardial amyloid content. In Aim 1, we will quantify myocardial 18F-florbetapir retention as a marker of aggressive myocardial disease in individuals with AL-CMP and active plasma cell dyscrasia compared to control individuals with AL-CMP and long-term hematological remission. In Aim 2, we propose, using advanced imaging, to assess the effects of light chain reduction due to chemotherapy on myocardial structure, function, and metabolism and define the time course of these changes. Serial ECV and strain imaging by CMR, serum F2-isoprostanes and peroxynitrite levels, myocardial oxidative metabolism (Kmono) and coronary flow reserve by 11C-acetate PET, and 18F-florbetapir imaging will not only intricately characterize the myocardial substrate in AL-CMP, but also identify changes in response to therapy. The proposed studies offer the potential to transform our current understanding of AL-CMP as a restrictive heart disease caused by passive amyloid-related architectural damage to that of a more complex disorder resulting from both passive and aggressive factors. The results of these studies may form the foundation for drug discovery programs to prevent and cure AL-CMP.
Interactions of environmental factors, immunity, and host-related factors likely trigger AL-amyloidosis, but have not yet been explored. Changes in metal ions and gut microbiota may be causal, representing the integrated effects of all these factors, or may be the downstream effect of systemic amyloid deposition in the organ systems. A plethora of recent literature strongly support the role of microbiota in the pathogenesis of several diseases, suggesting that gut microbiota changes with age, influences heart failure (HF) outcomes, and plays a role in the formation of β-amyloid deposits in Alzheimer's disease. Importantly, alterations in lifestyle, diet, prebiotics, probiotics, or phenols and gut microbiota may represent therapeutic and preventative strategies in amyloid disease, but it has not been explored in AL-amyloidosis. We propose to study the role of salivary and gut microbiome in AL amyloidosis.
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| Label | Type | Description | Intervention Names |
|---|---|---|---|
| Active AL cardiac amyloidosis | Experimental | 75 individuals with light chain systemic amyloidosis with active plasma cell dyscrasia and cardiac involvement will undergo a research F-18 florbetapir PET, C-11 acetate PET, and MRI of blood of the heart, as well as the heavy metal analysis of the blood at baseline, 6 months and 12 months after initiation of chemotherapy. 25 of these individuals will also undergo a N-13 ammonia PET scan of the heart following supine bicycle stress at baseline and at 6 months after initiation of chemotherapy. |
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| Remission AL cardiac amyloidosis | Active Comparator | 25 individuals with light chain systemic amyloidosis with cardiac involvement and plasma cell dyscrasia in hematological remission (complete hematological remission or very good partial response-differential free light chain (dFLC)<40 mg/dL for > 1 year prior to enrollment) will undergo a research F-18 florbetapir PET, C-11 acetate PET, and MRI scan of the heart as well as a heavy metal analysis of the blood at baseline. |
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| Active AL Pre-CMP | Experimental | 36 individuals with light chain systemic amyloidosis with active plasma cell dyscrasia and without cardiac involvement will undergo a research F-18 florbetapir PET, C-11 acetate PET, and MRI of the heart, as well as a heavy metal analysis of the blood at baseline. At 6 months they will undergo a research MRI of the heart and at 12 months they will have a clinical follow up. Subjects with contraindications to Cardiac MRI or gadolinium contrast may still be eligible for study participation. |
| Name | Type | Description | Arm Group Labels | Other Names |
|---|---|---|---|---|
| F-18 florbetapir/C-11 acetate PET | Radiation | F-18 florbetapir PET scan, C-11 acetate PET scan |
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| Measure | Description | Time Frame |
|---|---|---|
| Change in F-18 florbetapir myocardial retention index from baseline to 6 months and 12 months | quantitative measure of F-18 florbetapir uptake by the heart muscle | Baseline, 6 and 12 months |
| Change in Serum oxidative stress markers from baseline to 6 months and 12 months | serum F-2 isoprostane and peroxynitrite levels | Baseline, 6 and 12 months |
| Change in Myocardial oxidative metabolism markers from baseline to 6 months | K mono and coronary flow reserve obtained by C-11 acetate PET/CT at rest and stress | Baseline and 6 months |
| Change in Magnetic resonance imaging markers from baseline to 6 months and 12 months | Extracellular volume index, T-1 mapping, late gadolinium enhancement, global strain, left ventricular mass | Baseline, 6 and 12 months |
| Measure | Description | Time Frame |
|---|---|---|
| Change in Myocardial energy efficiency from baseline to 6 months | Myocardial energy efficiency, Kmono reserve, will be determined by C-11 acetate PET | Baseline and 6 months |
| Light Chain Toxicity |
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Inclusion criteria:
Age > 18 years
Diagnosis of light chain amyloidosis by standard criteria (immunofixation of serum and urine, IgG free light chain (FLC) assay, a biopsy of fat pad/ bone marrow, or organ biopsy, followed by typing of the light chain using immunohistochemistry or immunogold assay with confirmation by Mass spectroscopy as needed)
Willing and able to provide consent
Additional inclusion criteria for the Remission AL-CMP: Hematological response defined as complete hematological remission or very good partial response-differential free light chain (dFLC)<40 mg/dL for > 1 year prior to enrollment
Additional inclusion criteria for the Active AL-CMP - exercise: Ability to perform supine bicycle exercise. Enrollment to this arm will stop after 36 subjects complete baseline and 6 months studies.
Additional inclusion criteria for the Active AL Pre-CMP - Normal left ventricular wall thickness (≤ 12 mm) and normal LVEF (≥55%) on echocardiography within 3 months or increased wall thickness with normal cardiac biomarker levels: not meeting above definition.
Additional inclusion criteria for Control Multiple Myeloma subjects: diagnosis of multiple myeloma without concomitant amyloidosis by standard criteria
Additional inclusion criteria for Control Heart Failure subjects: diagnosis of heart failure without amyloidosis by standard criteria
Additional inclusion criteria for the active AL-CMP: Abnormal TnT 5th generation levels (>9 ng/L: Female, >14 ng/L: Male) or abnormal age appropriate N terminal pro-brain natriuretic peptide, NT-proBNP (abnormal values: <50 years: >450 pg/ml; 50-75 years:>900 pg/ml; >75 years: >1800 pg/ml)
Exclusion Criteria:
Additional exclusion criteria for microbiota study: Documented hypertrophic cardiomyopathy, HIV or chronic viral hepatitis, documented inflammatory bowel disease, systemic antibiotics, antivirals, antifungals or antiparasitic agents within 6 months, unable to mail the stool sample in a timely manner, bowel surgery, colon cancer, received chemotherapy, and pregnancy.
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| Name | Role | Phone | Extension | |
|---|---|---|---|---|
| Sharmila Dorbala, MD, MPH | Contact | 617-732-6290 | sdorbala@partners.org |
| Name | Affiliation | Role |
|---|---|---|
| Sharmila Dorbala, MD | Brigham and Women's Hospital (AHA and NIH Studies) | Principal Investigator |
| Rodney Falk, MD | Brigham and Women's Hospital (NIH Study) | Principal Investigator |
| Facility | Status | City | State | ZIP | Country | Contacts |
|---|---|---|---|---|---|---|
| Brigham and Womens' Hospital | Recruiting | Boston | Massachusetts | 02421 | United States |
| PubMed Identifier | Type | Citation | Retractions |
|---|---|---|---|
| 40938234 | Derived | Benz DC, Clerc OF, Cuddy SAM, Singh V, Kijewski MF, Bianchi G, Yee AJ, Ruberg FL, Jerosch-Herold M, Kwong RY, Di Carli MF, Liao R, Falk RH, Dorbala S. Changes in Myocardial Light Chain Amyloid Burden After Plasma Cell Therapy. JACC Cardiovasc Imaging. 2025 Dec;18(12):1363-1374. doi: 10.1016/j.jcmg.2025.07.017. Epub 2025 Sep 12. | |
| 39001736 | Derived | Clerc OF, Cuddy SAM, Jerosch-Herold M, Benz DC, Katznelson E, Canseco Neri J, Taylor A, Kijewski MF, Bianchi G, Ruberg FL, Di Carli MF, Liao R, Kwong RY, Falk RH, Dorbala S. Myocardial Characteristics, Cardiac Structure, and Cardiac Function in Systemic Light-Chain Amyloidosis. JACC Cardiovasc Imaging. 2024 Nov;17(11):1271-1286. doi: 10.1016/j.jcmg.2024.05.004. Epub 2024 Jul 10. |
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We do not have a plan to share individual participant data with other researchers
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| ID | Term |
|---|---|
| D000075363 | Immunoglobulin Light-chain Amyloidosis |
| D009202 | Cardiomyopathies |
| D000686 | Amyloidosis |
| ID | Term |
|---|---|
| D054219 | Neoplasms, Plasma Cell |
| D009370 | Neoplasms by Histologic Type |
| D009369 | Neoplasms |
| D057165 | Proteostasis Deficiencies |
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| Multiple Myeloma Controls | No Intervention | 25 individuals with diagnosis of multiple myeloma without concomitant amyloidosis by standard criteria will undergo urine and blood testing only. |
| Heart Failure | Experimental | 10 individuals with diagnosis of heart failure without amyloidosis by standard criteria will undergo a research F-18 florbetapir PET, C-11 acetate PET, and MRI of the heart, as well as a heavy metal analysis of the blood at baseline.. |
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| MRI | Device | Cardiac MRI with gadolinium contrast. |
|
| N-13 ammonia PET | Radiation | N-13 ammonia PET scan following supine bicycle stress. |
|
Study subject urine light chain's will be extracted and infused into zebrafish and isolated cardiomyocytes to study light chain toxicity
| Baseline |
| Understand the role of gut microbiota and heavy metals in the pathogenesis of AL Amyloidosis | This will be tested using machine learning methods with 16S rRNA sequencing of salivary and stool samples in a 40-patient cohort with AL-amyloidosis compared to healthy controls from the NIH funded human microbiome project (HMP).This will also be used to test if the gut microbiome affects amyloid formation using a transgenic mouse model of AL amyloidosis that expresses the human LC in the gut and develops amyloid in the stomach. | Baseline |
| Ronglih Liao, PhD |
| Stanford School of Medicine (AHA Study) |
| Principal Investigator |
| 38873265 | Derived | Katznelson E, Jerosch-Herold M, Cuddy SAM, Clerc OF, Benz DC, Taylor A, Rao S, Kijewski MF, Liao R, Landau H, Yee AJ, Ruberg FL, Di Carli MF, Falk RH, Kwong RY, Dorbala S. Mechanisms of left ventricular systolic dysfunction in light chain amyloidosis: a multiparametric cardiac MRI study. Front Cardiovasc Med. 2024 May 30;11:1371810. doi: 10.3389/fcvm.2024.1371810. eCollection 2024. |
| 34922860 | Derived | Cuddy SAM, Jerosch-Herold M, Falk RH, Kijewski MF, Singh V, Ruberg FL, Sanchorawala V, Landau H, Maurer MS, Yee AJ, Bianchi G, Di Carli MF, Liao R, Kwong RY, Dorbala S. Myocardial Composition in Light-Chain Cardiac Amyloidosis More Than 1 Year After Successful Therapy. JACC Cardiovasc Imaging. 2022 Apr;15(4):594-603. doi: 10.1016/j.jcmg.2021.09.032. Epub 2021 Dec 15. |
| 32417333 | Derived | Cuddy SAM, Bravo PE, Falk RH, El-Sady S, Kijewski MF, Park MA, Ruberg FL, Sanchorawala V, Landau H, Yee AJ, Bianchi G, Di Carli MF, Cheng SC, Jerosch-Herold M, Kwong RY, Liao R, Dorbala S. Improved Quantification of Cardiac Amyloid Burden in Systemic Light Chain Amyloidosis: Redefining Early Disease? JACC Cardiovasc Imaging. 2020 Jun;13(6):1325-1336. doi: 10.1016/j.jcmg.2020.02.025. Epub 2020 May 13. |
| D008659 | Metabolic Diseases |
| D009750 | Nutritional and Metabolic Diseases |
| D008232 | Lymphoproliferative Disorders |
| D007160 | Immunoproliferative Disorders |
| D007154 | Immune System Diseases |
| D010265 | Paraproteinemias |
| D006331 | Heart Diseases |
| D002318 | Cardiovascular Diseases |