Amyloidosis

AL is caused by overproduction of an amyloidogenic immunoglobulin light chain in patients with a monoclonal plasma cell or other B cell lymphoproliferative disorder. Light chains can also form nonfibrillar tissue deposits (ie, light chain deposition disease). Rarely, immunoglobulin heavy chains form amyloid fibrils (called AH amyloidosis).

Common sites for amyloid deposition include the skin, nerves, heart, gastrointestinal tract (including the tongue), kidneys, liver, spleen, and blood vessels. Usually, a low-grade plasmacytosis is present in the bone marrow, which is similar to that in multiple myeloma, although most patients do not have true multiple myeloma (with lytic bone lesions, hypercalcemia, renal tubular casts, and anemia). However, about 10 to 20% of patients with multiple myeloma develop AL amyloidosis.

AF is caused by inheritance of a gene encoding a mutated aggregation-prone serum protein, usually a protein abundantly produced by the liver.

Serum proteins that can cause AF include transthyretin (TTR), apolipoprotein A-I, apolipoprotein A-II, lysozyme, fibrinogen, gelsolin, and cystatin C. A form that is speculated to be familial is caused by the serum protein leukocyte chemotactic factor 2 (LECT2); however, a specific inherited gene mutation for this latter type has not been clearly demonstrated.

Amyloidosis caused by TTR (ATTR) is the most common type of AF. More than 130 mutations of the TTR gene have been associated with amyloidosis. The most prevalent mutation, V30M, is common in Portugal, Sweden, Brazil, and Japan, and a V122I mutation is present in about 4% of American and Caribbean Black people. Disease penetrance and age of onset are highly variable but are consistent within families and ethnic groups (1).

ATTR causes peripheral sensorimotor neuropathy and autonomic neuropathy, chronic kidney disease, and cardiomyopathy. Carpal tunnel syndrome commonly precedes other neurologic disease manifestations. Vitreous deposits may develop due to production of mutant TTR by the retinal epithelium, or leptomeningeal deposits may develop as the choroid plexus produces mutant TTR. When cardiomyopathy is the predominant manifestation of TTR deposition in the heart, it is referred to as transthyretin amyloid cardiomyopathy (ATTR-CM).

ATTRwt is caused by aggregation and deposition of wild-type TTR, principally targeting the heart.

ATTRwt is increasingly recognized as a cause of infiltrative cardiomyopathy in older men. Approximately 16% of patients with aortic stenosis undergoing transcatheter aortic valve replacement (2) and 13% of those hospitalized for heart failure with preserved ejection fraction (HFpEF) also have transthyretin amyloid cardiomyopathy, in this case designated as wATTR-CM to denote deposition of wild-type TTR in the heart (3). Soft-tissue manifestations of ATTRwt amyloid, including carpal tunnel syndrome, bicipital tendon rupture, rotator cuff tears, and spinal stenosis, may precede clinical expression of infiltrative cardiomyopathy by years.

The genetic and epigenetic factors leading to ATTRwt are unknown. Because ATTRwt and AL amyloidosis both can cause cardiomyopathy, and because amyloidogenic monoclonal gammopathies may be present in patients in this age group, it is essential to accurately type the amyloid so that patients with ATTRwt are not inappropriately treated with chemotherapy (which is used for AL).

This form can occur secondary to several infectious, inflammatory, and malignant conditions and is caused by aggregation of isoforms of the acute-phase reactant serum amyloid A.

Common causative infections include

• Tuberculosis

• Bronchiectasis

• Osteomyelitis

• Leprosy

Predisposing inflammatory conditions include

• Rheumatoid arthritis

• Juvenile idiopathic arthritis

• Crohn disease

• Inherited periodic fever syndromes such as familial Mediterranean fever

• Castleman disease

Inflammatory cytokines (eg, interleukin [IL]-1, tumor necrosis factor [TNF], IL-6) that are produced in these disorders or ectopically by tumor cells cause increased hepatic synthesis of serum amyloid A (SAA).

AA amyloidosis shows a predilection for the kidneys, spleen, liver, adrenal glands, and lymph nodes. Involvement of the heart or peripheral and autonomic nerves occurs late in the disease course.

Localized amyloidosis outside the brain is most frequently caused by deposits of clonal immunoglobulin light chains; within the brain, amyloid beta protein predominates.

Localized amyloid deposits typically involve the airways and lung tissue, bladder and ureters, skin, breasts, and eyes. Rarely, other locally produced proteins cause amyloidosis, such as keratin isoforms that can form deposits locally in the skin. Clonal immunoglobulin light chains produced by mucosal-associated lymphoid tissue in the gastrointestinal tract, airways, and bladder can lead to localized AL in those organs.

Amyloid beta protein deposits in the brain contribute to Alzheimer disease or cerebrovascular amyloid angiopathy. Other proteins produced in the central nervous system can misfold, aggregate, and damage neurons, leading to neurodegenerative diseases (eg, Parkinson disease, Huntington disease).

1. 1. Buxbaum JN, Ruberg FL: Transthyretin V122I (pV142I)* cardiac amyloidosis: an age-dependent autosomal dominant cardiomyopathy too common to be overlooked as a cause of significant heart disease in elderly African Americans. Genet Med 19(7):733-742, 2017. doi:10.1038/gim.2016.200

2. 2. Fabbri G, Serenelli M, Cantone A, et al: Transthyretin amyloidosis in aortic stenosis: clinical and therapeutic implications. Eur Heart J Suppl 23(Suppl E):E128-E132, 2021. doi:10.1093/eurheartj/suab107

3. 3. Magdi M, Mostafa MR, Abusnina W, et al: A systematic review and meta-analysis of the prevalence of transthyretin amyloidosis in heart failure with preserved ejection fraction. Am J Cardiovasc Dis 12(3):102-111, 2022. PMID: 35873185

Diagnosis of amyloidosis is made by demonstration of fibrillar deposits in an involved organ. Aspiration of subcutaneous abdominal fat detects amyloid deposits in about 80% of patients with AL but less than 25% of patients with ATTRwt (1). If the fat biopsy result is negative, a clinically involved organ should be biopsied. The diagnostic sensitivity of kidney and heart biopsies is nearly 100% when these organs are clinically involved. Tissue sections are stained with Congo red dye and examined with a polarizing microscope for characteristic birefringence. Nonbranching 10-nm fibrils can also be recognized by electron microscopy on biopsy specimens from the heart or kidneys.

Nuclear scanning using bone-avid tracers can diagnose ATTR amyloid cardiomyopathy without heart biopsy, provided AL amyloidosis is ruled out.

After amyloidosis has been confirmed by biopsy, the type is determined using a variety of techniques. For some types of amyloidosis, immunohistochemistry or immunofluorescence may be diagnostic, but false-positive typing results occur. Other useful techniques include gene sequencing for AF and biochemical identification by mass spectrometry to accurately identify protein variants in amyloid deposits (the most sensitive and specific method).

If AL is suspected, patients should be evaluated for an underlying plasma cell disorder using quantitative measurement of serum free immunoglobulin light chains, qualitative detection of serum or urine monoclonal light chains using immunofixation electrophoresis (serum protein electrophoresis and urine protein electrophoresis are insensitive in patients with AL), and a bone marrow biopsy with flow cytometry or immunohistochemistry to establish plasma cell clonality.

Patients with > 10% clonal plasma cells should be tested to see if they meet criteria for multiple myeloma, including screening for lytic bone lesions, anemia, renal insufficiency, and hypercalcemia.

Patients are screened for organ involvement beginning with noninvasive testing:

• Kidneys: Urinalysis; measurement of serum BUN, creatinine, and albumin; estimated glomerular filtration rate (eGFR); and 24-hour urine collection for protein electrophoresis (UPEP)

• Liver: Liver function tests

• Lungs: Chest x-ray, chest CT, and pulmonary function tests

• Heart: ECG and measurement of biomarkers such as brain (B-type) natriuretic peptide (BNP) or N-terminal-pro-BNP (NT-proBNP) and troponin

Cardiac involvement can be suggested by low voltage on ECG (caused by a thickened ventricle) and/or dysrhythmias. If cardiac involvement is suspected because of symptoms, in addition to ECG findings and cardiac biomarkers, echocardiography is done to measure diastolic relaxation and global longitudinal strain (a measure of left ventricular systolic function) and to screen for biventricular hypertrophy. In ambiguous cases, cardiac MRI can be done to detect persistent subendocardial gadolinium enhancement, a characteristic finding. Cardiac technetium pyrophosphate nuclear scans improve detection of ATTR amyloid heart disease and can avoid the need for heart biopsies provided blood tests rule out AL amyloidosis (2, 3).

1. 1. Aimo A, Emdin M, Musetti V, et al: Abdominal Fat Biopsy for the Diagnosis of Cardiac Amyloidosis. JACC Case Rep 2(8):1182-1185, 2020. doi:10.1016/j.jaccas.2020.05.062

2. 2. Gillmore JD, Maurer MS, Falk RH, et al: Nonbiopsy diagnosis of cardiac transthyretin amyloidosis. Circulation 133(24):2404–2412, 2016.

3. 3. Maurer MS, Bokhari S, Damy T, et al: Expert consensus recommendations for the suspicion and diagnosis of transthyretin cardiac amyloidosis. Circ Heart Fail 12(9):e006075, 2019.

Supportive care measures are directed at the affected organ system:

• Renal: Patients with nephrotic syndrome and edema should be treated with salt and fluid restriction, and loop diuretics; because of the ongoing protein loss, protein intake should not be restricted. Kidney transplantation is an option when the underlying disease process is controlled, and can provide long-term survival comparable to that in other renal diseases.

• Cardiac: Patients with cardiomyopathy should be treated with salt and fluid restriction and loop diuretics. Other medications for heart failureHeart transplantation has been successful in carefully selected patients with AL or ATTR amyloidosis and severe cardiac involvement. To prevent recurrence in the transplanted heart, patients with AL amyloidosis must be given aggressive chemotherapy directed at the clonal plasma cell disorder, and patients with symptomatic ATTR amyloid polyneuropathy or cardiomyopathy should be considered for anti-TTR therapies.

• Gastrointestinal:

• Nervous system: In patients with peripheral neuropathy

Orthostatic hypotension

For AL amyloidosis:

• Prompt initiation of anti-plasma cell therapy is essential to preserve organ function and prolong life.

Most medications used for multiple myeloma have been used in AL amyloidosis; choice of medication, dose, and schedule often must be modified when organ function is impaired.

stem cell transplantation can be highly effective in selected patients (1).

²) showed an unprecedented high rate of hematologic response (2). Hematologic response is based on monoclonal protein in serum and urine levels determined by immunofixation electrophoresis and serum light chain levels with kappa/lambda ratios. However, long-term survival data are lacking.

All available treatments target clonal B-cells or plasma cells in AL amyloidosis. Studies of antifibril antibodies, such as birtamimab and CAEL-101, are in progress (3).

Localized AL amyloidosis can be treated with low-dose external beam radiation therapy because plasma cells are highly radiosensitive.

For ATTR amyloidosis:

• Liver transplantation

• Tetramer-stabilizing medications

• Gene silencing medications

Liver transplantation—which replaces the primary site of synthesis of the mutant protein with a new organ producing normal TTR—can be effective in certain TTR mutations if done at disease onset (early neuropathy and no heart involvement). Transplantation later in the course of the disease often leads to progressive amyloid cardiomyopathy and neuropathy due to the misfolding and deposition of wild-type TTR protein onto pre-existing amyloid deposits.

4, 5).

TTR gene silencing using anti-sense RNA or RNA interference to block translation of TTR mRNA efficiently reduces serum levels of TTR, improves neurologic outcomes in about 50% of patients, and, in some patients, appears capable of repairing injured nerves (6, 7

8). Preliminary data from another trial suggests that gene silencers may be effective in the treatment of cardiomyopathy in patients with ATTR amyloidosis (9).

For ATTRwt amyloidosis:

• Tetramer-stabilizing medications

5). Clinical trials are underway examining the effect of TTR gene silencers on the cardiomyopathy that occurs in patients with ATTRwt amyloidosis as well as the cardiomyopathy that occurs in patients with ATTR amyloidosis characterized by the mutant protein (10).

Unlike hereditary ATTR amyloidosis, liver transplantation is not effective for patients with ATTRwt because the amyloidogenic protein is a structurally normal TTR.

For other AA types, treatment is directed at the underlying infection, inflammatory disease, or cancer.

1. 1. Sanchorawala V, Sun F, Quillen K, et al: Long-term outcome of patients with AL amyloidosis treated with high-dose melphalan and stem cell transplantation: 20-year experience. Blood 126: 2345–2347, 2015. doi: 10.1182/blood-2015-08-662726

2. 2. Kastritis E, Palladini G, Minnema MC, et al: Daratumumab-Based Treatment for Immunoglobulin Light-Chain Amyloidosis. N Engl J Med 385(1):46-58, 2021. doi:10.1056/NEJMoa2028631

3. 3. Quarta CC, Fontana M, Damy T, et al: Changing paradigm in the treatment of amyloidosis: From disease-modifying drugs to anti-fibril therapy. Front Cardiovasc Med 9:1073503, 2022. doi:10.3389/fcvm.2022.1073503

4. 4. Berk JL, Suhr OB, Obici L, et al: Repurposing diflunisal for familial amyloid polyneuropathy: a randomized clinical trial. JAMA 310: 2658–2667, 2013. doi: 10.1001/jama.2013.283815

5. 5. Maurer MS, Schwartz JH, Gundapaneni B, et al: Tafamidis treatment for patients with transthyretin amyloid cardiomyopathy. N Engl J Med 379:1007–1016, 2018.

6. 6. Adams D, Gonzalez-Duarte A, O'Riordan WD, et al: Patisiran, an RNAi therapeutic, for hereditary transthyretin amyloidosis. N Engl J Med 379:11–21, 2018.

7. 7. Benson MD, Waddington-Cruz M, Berk JL, et al: Inotersen treatment for patients with transthyretin amyloidosis. N Engl J Med 379:22–31, 2018.

8. 8. Adams D, Tournev IL, Taylor MS, et al: Efficacy and safety of vutrisiran for patients with hereditary transthyretin-mediated amyloidosis with polyneuropathy: a randomized clinical trial. Amyloid 30(1):1-9, 2023. doi:10.1080/13506129.2022.2091985

9. 9. Maurer MS, Fontanta MA, Berk JL, et al: Primary results from APOLLO-B, a phase 3 study of patisiran in patients with transthyretin-mediated amyloidosis with cardiomyopathy. Abstract presented at International Symposium of Amyloidosis, September 2022,Heidelberg Germany.

10. 10. Writing Committee, Kittleson MM, Ruberg FL, et al: 2023 ACC Expert Consensus Decision Pathway on Comprehensive Multidisciplinary Care for the Patient With Cardiac Amyloidosis: A Report of the American College of Cardiology Solution Set Oversight Committee [published correction appears in J Am Coll Cardiol 81(11):1135, 2023]. J Am Coll Cardiol 81(11):1076-1126, 2023. doi:10.1016/j.jacc.2022.11.022