AUTHOR AND EDITOR INFORMATION

Section 1 of 11  

• Authors and Editors
• Definition of Amyloidosis
• Classification Systems: Historical (Clinical Based) and Modern (Biochemical Based)
• Systemic Amyloidoses
• Hereditary Renal Amyloidoses
• Central Nervous System Amyloidoses and Other Localized Amyloidoses
• Nonfibrillar Components of Amyloid
• Mechanisms of Amyloid Formation
• Approach To Diagnosing Amyloidosis
• Multimedia
• References

DEFINITION OF AMYLOIDOSIS

Section 2 of 11  

• Authors and Editors
• Definition of Amyloidosis
• Classification Systems: Historical (Clinical Based) and Modern (Biochemical Based)
• Systemic Amyloidoses
• Hereditary Renal Amyloidoses
• Central Nervous System Amyloidoses and Other Localized Amyloidoses
• Nonfibrillar Components of Amyloid
• Mechanisms of Amyloid Formation
• Approach To Diagnosing Amyloidosis
• Multimedia
• References

Amyloidosis is a clinical disorder caused by extracellular deposition of insoluble abnormal fibrils that injure tissue. The fibrils are formed by the aggregation of misfolded, normally soluble proteins. In humans, about 23 different unrelated proteins are known to form amyloid fibrils in vivo. All types of amyloid consist of a major fibrillar protein that defines the type of amyloid (approximately 90%) plus various minor components. Although each type of fibril may be associated with a distinct clinical picture, all share certain physical and pathologic properties, as follows:

• Amorphous eosinophilic appearance on light microscopy after hematoxylin and eosin staining (see Image 1)
• Bright green fluorescence observed under polarized light after Congo red staining (see Image 2)
• Regular fibrillar structure as observed by electron microscopy
• Beta pleated sheet structure as observed by x-ray diffraction
• Solubility in water and buffers of low ionic strength

For excellent patient education resources, visit eMedicine's Brain and Nervous System Center. Also, see eMedicine's patient education article Mad Cow Disease and Variant Creutzfeldt-Jakob Disease.

CLASSIFICATION SYSTEMS: HISTORICAL (CLINICAL BASED) AND MODERN (BIOCHEMICAL BASED)

Section 3 of 11  

• Authors and Editors
• Definition of Amyloidosis
• Classification Systems: Historical (Clinical Based) and Modern (Biochemical Based)
• Systemic Amyloidoses
• Hereditary Renal Amyloidoses
• Central Nervous System Amyloidoses and Other Localized Amyloidoses
• Nonfibrillar Components of Amyloid
• Mechanisms of Amyloid Formation
• Approach To Diagnosing Amyloidosis
• Multimedia
• References

Historical classification systems (clinical based)

Until the early 1970s, the idea of a single amyloid substance predominated. Various descriptive classification systems were proposed based on the organ distribution of amyloid deposits and clinical findings. Most classification systems included primary (ie, in the sense of idiopathic) amyloidosis, in which no associated clinical condition was identified, and secondary amyloidosis, ie, associated with chronic inflammatory conditions. Some classification systems included myeloma-associated, familial, and localized amyloidosis.

The modern era of amyloidosis classification began in the late 1960s with the development of methods to solubilize amyloid fibrils. These methods permitted chemical amyloid studies. Descriptive terms such as primary amyloidosis, secondary amyloidosis, and others (eg, senile amyloidosis), which are not based on etiology, provide little useful information and are no longer recommended.

Modern amyloidosis classification (biochemical based)

Amyloid is now classified chemically. The amyloidoses are referred to with a capital A (for amyloid) followed by an abbreviation for the fibril protein. For example, in most cases formerly called primary amyloidosis and in myeloma-associated amyloidosis, the fibril protein is an immunoglobulin light chain or light chain fragment (abbreviated L); thus, patients with these amyloidoses are now said to have light chain amyloidosis (AL). Similarly, in most cases previously termed senile cardiac amyloidosis and in many cases previously termed familial amyloid polyneuropathy, the fibrils consist of the transport protein transthyretin (TTR); these diseases are now termed ATTR.

Proteins that form amyloid fibrils differ in size function, amino acid sequence, and native structure but become insoluble aggregates that are similar in structure and properties. Protein misfolding results in formation of fibrils that show a common beta sheet pattern based on x-ray diffraction.

Twenty-three different fibril proteins are described in human amyloidosis with variable clinical features. The major types of human amyloid are outlined and discussed individually in Table 1.

Table 1. Human Amyloidoses

* Islet amyloid polypeptide amyloidosis

SYSTEMIC AMYLOIDOSES

Section 4 of 11  

• Authors and Editors
• Definition of Amyloidosis
• Classification Systems: Historical (Clinical Based) and Modern (Biochemical Based)
• Systemic Amyloidoses
• Hereditary Renal Amyloidoses
• Central Nervous System Amyloidoses and Other Localized Amyloidoses
• Nonfibrillar Components of Amyloid
• Mechanisms of Amyloid Formation
• Approach To Diagnosing Amyloidosis
• Multimedia
• References

A amyloidosis

The precursor protein is a normal-sequence apo-SAA (serum amyloid A protein), which is an acute phase reactant that circulates in the serum bound to high-density lipoprotein.

A amyloidosis (AA) occurs in various chronic inflammatory disorders, chronic local or systemic microbial infections, and, occasionally, with neoplasms. Some of the conditions associated with AA include the following:

• Rheumatoid arthritis
• Juvenile chronic arthritis
• Ankylosing spondylitis
• Psoriasis and psoriatic arthritis
• Adult Still disease and Behçet syndrome
• Familial Mediterranean fever
• Crohn disease
• Leprosy
• Osteomyelitis
• Tuberculosis
• Chronic bronchiectasis
• Castleman disease
• Hodgkin disease
• Renal cell carcinoma
• Carcinoma of the gut, lung, or urogenital tract

Typical organs involved include the kidney, liver, and spleen. Worldwide, AA is the most common systemic amyloidosis; it was formerly termed secondary amyloidosis. Colchicine prevents renal failure due to amyloid deposition in familial Mediterranean fever; no proven therapy exists in settings other than the treatment of underlying inflammatory condition and the reduced production of the precursor protein apo-SAA. For details, see Amyloidosis, AA (Inflammatory).

Light chain amyloidosis

The precursor protein is a clonal immunoglobulin light chain or light chain fragment. AL is a monoclonal plasma cell disorder closely related to multiple myeloma; some patients fulfill diagnostic criteria for multiple myeloma. Typical organs involved include the heart, kidney, peripheral nerve, gastrointestinal tract, respiratory tract, and nearly any other organ. AL includes former designations of primary amyloidosis and myeloma-associated amyloidosis. Treatment usually mirrors the management of multiple myeloma (ie, chemotherapy). Selected patients have received benefit from high-dose melphalan and autologous stem-cell transplantation, with reports of prolonged survival in recent studies. Iododoxorubicin, a molecule that binds to and solubilizes amyloid fibrils, is undergoing clinical study. For more information, see Amyloidosis, Immunoglobulin-Related.

Heavy chain amyloidosis

In a few cases, immunoglobulin chain amyloidosis fibrils contain only heavy chain sequences rather than light chain sequences, and the disease is termed heavy chain amyloidosis (AH) rather than AL. For more information, see Amyloidosis, Immunoglobulin-Related.

Transthyretin amyloidosis

The precursor protein is the normal- or mutant-sequence TTR, a transport protein synthesized in the liver and choroid plexus. TTR is a tetramer of 4 identical subunits of 127 amino acids each. Normal-sequence TTR forms amyloid deposits in the cardiac ventricles of elderly people (ie, >70 y); this disease is also termed senile cardiac amyloidosis. The prevalence of TTR cardiac amyloidosis increases progressively with age, affecting 25% or more of the population older than 90 years. Normal-sequence ATTR can be an incidental autopsy finding, or it can cause clinical symptoms (eg, heart failure, arrhythmias).

Point mutations in TTR increase the tendency of TTR to form amyloid. Amyloidogenic TTR mutations are inherited as an autosomal dominant disease with variable penetrance. More than 60 amyloidogenic TTR mutations are known. The most prevalent TTR mutations are TTR Val30Met (common in Portugal, Japan, and Sweden), and TTR Val122Ile (carried by 3.9% of African Americans). Amyloidogenic TTR mutations cause deposits primarily in the peripheral nerves, heart, gastrointestinal tract, and vitreous.

Treatment for mutant-sequence amyloidogenic TTR is liver transplantation or supportive care. For normal-sequence amyloidogenic TTR, the treatment is supportive care. For details, see Amyloidosis, Transthyretin-Related.

Beta₂-microglobulin amyloidosis

The precursor protein is a normal beta₂-microglobulin (b₂M), which is the light chain component of the major histocompatibility complex. In the clinical setting, Ab₂M is associated with patients on dialysis and, rarely, patients with renal failure who are not on dialysis.

b₂M is normally catabolized in the kidney. In patients with renal failure, the protein accumulates in the serum. Conventional dialysis membranes do not remove b₂M; therefore, serum levels can reach as high as 30-60 times the reference range values in patients on hemodialysis. Musculoskeletal involvement is common and is characterized by deposits in the carpal ligaments, synovium, and bone, resulting in carpal tunnel syndrome, destructive arthropathy, bone cysts, and fractures. Other organs involved include the heart, gastrointestinal tract, liver, lungs, prostate, adrenals, and tongue.

Treatment includes renal transplantation, which may arrest amyloid progression. For details, see Amyloidosis, Beta2M (Dialysis-Related).

HEREDITARY RENAL AMYLOIDOSES

Section 5 of 11  

• Authors and Editors
• Definition of Amyloidosis
• Classification Systems: Historical (Clinical Based) and Modern (Biochemical Based)
• Systemic Amyloidoses
• Hereditary Renal Amyloidoses
• Central Nervous System Amyloidoses and Other Localized Amyloidoses
• Nonfibrillar Components of Amyloid
• Mechanisms of Amyloid Formation
• Approach To Diagnosing Amyloidosis
• Multimedia
• References

Consider these diseases when a renal biopsy demonstrates amyloid deposition and when they are likely diagnoses (rather than AL or AA) because the family history suggests an autosomal dominant disease. Again, the definitive diagnosis is made using immunohistologic staining of the biopsy material with antibodies specific for the candidate amyloid precursor proteins. For details, see Amyloidosis, Familial Renal.

Apolipoprotein AI amyloidosis (AapoAI) is an autosomal dominant amyloidosis caused by point mutations in the apoAI gene. Usually, this amyloidosis is a prominent renal amyloid. Some kindreds have peripheral neuropathy or cardiac disease. ApoAI (likely of normal sequence) also is the fibril precursor in localized amyloid plaques in the aortae of elderly people.

Fibrinogen amyloidosis (AFib) is an autosomal dominant amyloidosis caused by point mutations in the fibrinogen alpha chain gene.

Lysozyme amyloidosis (ALys) is an autosomal dominant amyloidosis caused by point mutations in the lysozyme gene.

Apolipoprotein AII amyloidosis (AapoAII) is an autosomal dominant amyloidosis caused by point mutations in the apoAII gene. The 2 kindreds described with this disorder have each carried a point mutation in the stop codon, leading to production of an abnormally long protein.

CENTRAL NERVOUS SYSTEM AMYLOIDOSES AND OTHER LOCALIZED AMYLOIDOSES

Section 6 of 11  

• Authors and Editors
• Definition of Amyloidosis
• Classification Systems: Historical (Clinical Based) and Modern (Biochemical Based)
• Systemic Amyloidoses
• Hereditary Renal Amyloidoses
• Central Nervous System Amyloidoses and Other Localized Amyloidoses
• Nonfibrillar Components of Amyloid
• Mechanisms of Amyloid Formation
• Approach To Diagnosing Amyloidosis
• Multimedia
• References

Central nervous system amyloidoses

Beta protein amyloid

The amyloid beta precursor protein (AbPP), which is a transmembrane glycoprotein, is the precursor protein in beta protein amyloid (Ab). Three distinct clinical settings are as follows:

1. Alzheimer disease has a normal-sequence protein, except in some cases of familial Alzheimer disease, in which mutant beta protein is inherited in an autosomal dominant manner.
2. Down syndrome has a normal-sequence protein that forms amyloids in most patients by the fifth decade of life.
3. Hereditary cerebral hemorrhage with amyloidosis (HCHWA), Dutch type, is inherited in an autosomal dominant manner. The beta protein contains a point mutation. These patients typically present with cerebral hemorrhage followed by dementia.

Prion protein amyloidosis

The precursor protein in prion protein amyloidosis (APrP) is a prion protein, which is a plasma membrane glycoprotein. The etiology is either infectious (ie, kuru) or genetic (ie, Creutzfeldt-Jakob disease [CJD], Gerstmann-Sträussler-Scheinker [GSS] syndrome, fatal familial insomnia [FFI]). The infectious unit is the prion protein, which induces a conformational change in a homologous protein encoded by a host chromosomal gene. Patients with CJD, GSS, and FFI carry autosomal dominant amyloidogenic mutations in the prion protein gene; therefore, the amyloidosis forms even in the absence of an infectious trigger.

Similar infectious animal disorders include scrapie in sheep and goats and bovine spongiform encephalitis (ie, mad cow disease).

Cystatin C amyloidosis

The precursor protein in cystatin C amyloidosis (ACys) is cystatin C, which is a cysteine protease inhibitor that contains a point mutation. This condition is clinically termed HCHWA, Icelandic type.

ACys is autosomal dominant. Clinical presentation includes multiple strokes and mental status changes beginning in the second or third decade of life. Many of the patients die by age 40 years. This disease is documented in a 7-generation pedigree in northwest Iceland. The pathogenesis is one of mutant cystatin that is widely distributed in tissues, but fibrils form only in the cerebral vessels; therefore, local conditions must play a role in fibril formation.

Non-amyloid beta cerebral amyloidosis (chromosome 13 dementias)

Two syndromes (British and Danish familial dementia) that share many aspects of clinical Alzheimer disease have been identified. Findings include the presence of neurofibrillary tangles, parenchymal preamyloid and amyloid deposits, cerebral amyloid angiopathy, and amyloid-associated proteins. Both conditions have been linked to specific mutations on chromosome 13; they cause abnormally long protein products (ABri and ADan) that ultimately result in different amyloid fibrils.

Other localized amyloidoses

Gelsolin amyloidosis

The precursor protein in gelsolin amyloidosis (AGel) is the actin-modulating protein gelsolin. Amyloid fibrils include a gelsolin fragment that contains a point mutation. Two amyloidogenic gelsolin mutations are described. One example is Asp187Asn, which is endemic in southeast Finland.

Clinical characteristics include slowly progressive cranial neuropathies, distal peripheral neuropathy, and lattice corneal dystrophy.

Atrial natriuretic factor amyloidosis

The precursor protein is atrial natriuretic factor (ANF), a hormone controlling salt and water homeostasis, and it is synthesized by the cardiac atria. Amyloid deposits are localized to the cardiac atria. This condition is highly prevalent in elderly people and generally is of little clinical significance. Atrial natriuretic factor amyloidosis (AANF) is most common in patients with long-standing congestive heart failure, presumably because of persistent ANF production. No relation exists to the amyloidoses that involve the cardiac ventricles (ie, AL, ATTR).

Keratoepithelin amyloidosis and lactoferrin amyloidosis

Point mutations occur in a gene termed BIGH3, which encodes keratoepithelin and leads to autosomal dominant corneal dystrophies characterized by the accumulation of corneal amyloid. Some BIGH3 mutations cause amyloid deposits, and others cause nonfibrillar corneal deposits. Another protein, lactoferrin, is also reported as the major fibril protein in familial subepithelial corneal amyloidosis. The relationship between keratoepithelin and lactoferrin in familial corneal amyloidosis is not yet clear.

Calcitonin amyloid

In calcitonin amyloid (ACal), the precursor protein is calcitonin, a calcium regulatory hormone synthesized by the thyroid. Patients with medullary carcinoma of the thyroid may develop localized amyloid deposition in the tumors, consisting of normal-sequence procalcitonin (ACal). The presumed pathogenesis is increased local calcitonin production, leading to a sufficiently high local concentration of the peptide and causing polymerization and fibril formation.

Islet amyloid polypeptide amyloidosis

In islet amyloid polypeptide amyloidosis (AIAPP), the precursor protein is an islet amyloid polypeptide (IAPP), also known as amylin. IAPP is a protein secreted by the islet beta cells that are stored with insulin in the secretory granules and released in concert with insulin. Normally, IAPP modulates insulin activity in skeletal muscle. IAPP amyloid is found in insulinomas and in the pancreas of many patients with diabetes mellitus type 2.

Prolactin amyloid

In prolactin amyloid (Apro), prolactin or prolactin fragments are found in the pituitary amyloid. This condition is often observed in elderly people and has also been reported in an amyloidoma in a patient with a prolactin-producing pituitary tumor.

Keratin amyloid

Some forms of cutaneous amyloid react with antikeratin antibodies. The identity of the fibrils is not chemically confirmed in keratin amyloid (Aker).

Medin amyloid

Aortic medial amyloid occurs in most people older than 60 years. Medin amyloid (AMed) is derived from a proteolytic fragment of lactadherin, a glycoprotein expressed by mammary epithelium.

NONFIBRILLAR COMPONENTS OF AMYLOID

Section 7 of 11  

• Authors and Editors
• Definition of Amyloidosis
• Classification Systems: Historical (Clinical Based) and Modern (Biochemical Based)
• Systemic Amyloidoses
• Hereditary Renal Amyloidoses
• Central Nervous System Amyloidoses and Other Localized Amyloidoses
• Nonfibrillar Components of Amyloid
• Mechanisms of Amyloid Formation
• Approach To Diagnosing Amyloidosis
• Multimedia
• References

All types of amyloid deposits contain not only the major fibrillar component (solubility in water, buffers of low ionic strength) but also nonfibrillar components that are soluble in conventional ionic strength buffers. The role of the minor components in amyloid deposition is not clear. These components do not appear to be absolutely required for fibril formation, but they may enhance fibril formation or stabilize formed fibrils.

The nonfibrillar components, contained in all types of amyloid, include the following:

• Pentagonal component
• • Pentagonal (P) component comprises approximately 5% of the total protein in amyloid deposits. This component is derived from the circulating serum amyloid P (SAP) component, which behaves as an acute phase reactant. The P component is one of the pentraxin group of proteins, with homology to C-reactive protein. In experimental animals, amyloid deposition is slowed without the P component.
  • Radiolabeled material homes to amyloid deposits; therefore, this component can be used in amyloid scans to localize and quantify amyloidosis and to monitor therapy response. Radiolabeled P component scanning has proven clinically useful in England, where the technology was developed, but it is available in only a few centers worldwide.
• Apolipoprotein E
• • Apolipoprotein E (apoE) is found in all types of amyloid deposits.
  • One allele, ApoE4, increases the risk for beta protein deposition, which is associated with Alzheimer disease. ApoE4 as a risk factor for other forms of amyloidosis is controversial.
  • The role of apoE in amyloid formation is not known.
• Glycosaminoglycans
• • Glycosaminoglycans (GAGs) are heteropolysaccharides composed of long unbranched polysaccharides that contain a repeating disaccharide unit. These proteoglycans are basement membrane components intimately associated with all types of tissue amyloid deposits. Amyloidotic organs contain increased amounts of GAGS, which may be tightly bound to amyloid fibrils. Heparan sulfate and dermatan sulfate are the GAGs most often associated with amyloidosis.
  • Heparan sulfate and dermatan sulfate have an unknown role in amyloidogenesis. Studies of AA and AL amyloid have shown marked restriction of the heterogeneity of the glycosaminoglycan chains, suggesting that particular subclasses of heparan and dermatan sulfates are involved.
  • Compounds that bind to heparan sulfate proteoglycans (eg, anionic sulfonates) decrease fibril deposition in murine models of AA and have been suggested as potential therapeutic agents.
• Other components found in some types of amyloid include complement components, proteases, and membrane constituents.

MECHANISMS OF AMYLOID FORMATION

Section 8 of 11  

• Authors and Editors
• Definition of Amyloidosis
• Classification Systems: Historical (Clinical Based) and Modern (Biochemical Based)
• Systemic Amyloidoses
• Hereditary Renal Amyloidoses
• Central Nervous System Amyloidoses and Other Localized Amyloidoses
• Nonfibrillar Components of Amyloid
• Mechanisms of Amyloid Formation
• Approach To Diagnosing Amyloidosis
• Multimedia
• References

Amyloid protein structures

In all forms of amyloidosis, the cell secretes the precursor protein in a soluble form that becomes insoluble at some tissue site, compromising organ function. All the amyloid precursor proteins are relatively small (ie, molecular weights 4000-25,000) and do not share any amino acid sequence homology. The secondary protein structures of most soluble precursor proteins (except for SAA and chromosomal prion protein [Prpc]) have substantial beta pleated sheet structure, while extensive beta sheet structure occurs in all of the deposited fibrils.

In some cases, hereditary abnormalities (primarily point mutations) in the precursor proteins are always present (eg, lysozyme, fibrinogen, cystatin C, gelsolin). In other cases, fibrils form from normal-sequence molecules (eg, AL, b₂M). In other cases, normal-sequence proteins can form amyloid, but mutations accelerate the process (eg, TTR, beta protein precursor).

Deposition location

In localized amyloidoses, the deposits form close to the precursor synthesis site; however, in systemic amyloidoses, the deposits may form either locally or at a distance from the precursor-producing cells. Amyloid deposits primarily are extracellular, but reports exist of fibrillar structures within macrophages and plasma cells.

Proteolysis and protein fragments

In some types of amyloidosis (eg, always in AA, often in AL, ATTR), the amyloid precursors undergo proteolysis, which may enhance folding into an amyloidogenic structural intermediate. Also, some of the amyloidoses may have a normal proteolytic process that is disturbed, yielding a high concentration of an amyloidogenic intermediate. The factors that lead to different organ tropism for the different amyloidoses are unknown.

Whether the proteolysis occurs before or after tissue deposition is unclear in patients in whom protein fragments are observed in tissue deposits. In some types of amyloid (eg, AL, Ab, ATTR), nonfibrillar forms of the same molecules can accumulate before fibril formation; thus, nonfibrillar deposits, in some cases, may represent intermediate deposition.

APPROACH TO DIAGNOSING AMYLOIDOSIS

Section 9 of 11  

• Authors and Editors
• Definition of Amyloidosis
• Classification Systems: Historical (Clinical Based) and Modern (Biochemical Based)
• Systemic Amyloidoses
• Hereditary Renal Amyloidoses
• Central Nervous System Amyloidoses and Other Localized Amyloidoses
• Nonfibrillar Components of Amyloid
• Mechanisms of Amyloid Formation
• Approach To Diagnosing Amyloidosis
• Multimedia
• References

Pathologic diagnosis (Congo red staining and immunohistochemistry)

Amyloidosis is diagnosed when Congo red–binding material is demonstrated in a biopsy specimen. Because different types of amyloidosis require different approaches to treatment, determining only that a patient has a diagnosis of amyloidosis is no longer adequate. A clinical situation may suggest the type of amyloidosis, but the diagnosis generally must be confirmed by immunostaining a biopsy specimen. Antibodies against the major amyloid fibril precursors are commercially available. For example, AL, ATTR, and Ab₂M can present as carpal tunnel syndrome or gastrointestinal amyloidosis, but each has a different etiology and requires a different treatment approach.

Similarly, determining whether the amyloid is of the AL or ATTR type is often difficult in patients with cardiac amyloidosis, because the clinical picture is usually similar. Without immunostaining to identify the type of deposited protein, an incorrect diagnosis can lead to ineffective and, perhaps, harmful treatment. Be wary of drawing diagnostic conclusions from indirect tests (eg, monoclonal serum proteins) because the results of these presumptive diagnostic tests can be misleading; for example, monoclonal serum immunoglobulins are common in patients older than 70 years, but the most common form of cardiac amyloidosis is derived from TTR.

Diagnosis by subcutaneous fat aspiration

For many years, rectal biopsy was the first procedure of choice. An important clinical advance was the recognition that the capillaries in the subcutaneous fat are often involved in patients with systemic amyloidosis and can often provide sufficient tissue for the diagnosis of amyloid, immunostaining, and, in some cases, amino acid sequence analysis; thus, biopsy of the organ with the most severe clinical involvement is often unnecessary.

For example, in cardiac amyloidosis, the definitive diagnosis of the type of amyloid can be made using an endomyocardial biopsy specimen, with Congo red and immunologic staining of the tissue sample. Alternatively, when noninvasive testing suggests cardiac amyloidosis, a specific diagnosis is often made by studying a subcutaneous fat aspiration instead of endomyocardial biopsy, thereby avoiding an invasive procedure.

Organ biopsies

When the subcutaneous fat aspiration biopsy does not provide information to reach a firm diagnosis, biopsies can be obtained from other organs. In addition, an advantage to performing a biopsy of an involved organ (eg, kidney, heart) is that it definitively establishes a cause-and-effect relationship between the organ dysfunction and amyloid deposition.

Other sites that are often sampled include the salivary glands, stomach, and bone marrow.

MULTIMEDIA

Section 10 of 11  

• Authors and Editors
• Definition of Amyloidosis
• Classification Systems: Historical (Clinical Based) and Modern (Biochemical Based)
• Systemic Amyloidoses
• Hereditary Renal Amyloidoses
• Central Nervous System Amyloidoses and Other Localized Amyloidoses
• Nonfibrillar Components of Amyloid
• Mechanisms of Amyloid Formation
• Approach To Diagnosing Amyloidosis
• Multimedia
• References

Media file 1:  Amorphous eosinophilic interstitial amyloid observed on a renal biopsy.
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Media type:  Photo

Media file 2:  Congo red staining of a cardiac biopsy specimen containing amyloid, viewed under polarized light.
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Media type:  Photo

REFERENCES

Section 11 of 11

• Authors and Editors
• Definition of Amyloidosis
• Classification Systems: Historical (Clinical Based) and Modern (Biochemical Based)
• Systemic Amyloidoses
• Hereditary Renal Amyloidoses
• Central Nervous System Amyloidoses and Other Localized Amyloidoses
• Nonfibrillar Components of Amyloid
• Mechanisms of Amyloid Formation
• Approach To Diagnosing Amyloidosis
• Multimedia
• References

• Benson MD. Aging, amyloid, and cardiomyopathy. N Engl J Med. Feb 13 1997;336(7):502-4. [Medline].
• Booth DR, Gillmore JD, Lachmann HJ. The genetic basis of autosomal dominant familial Mediterranean fever. QJM. Apr 2000;93(4):217-21. [Medline].
• Botto M, Hawkins PN, Bickerstaff MC. Amyloid deposition is delayed in mice with targeted deletion of the serum amyloid P component gene. Nat Med. Aug 1997;3(8):855-9. [Medline].
• Duston MA, Skinner M, Meenan RF. Sensitivity, specificity, and predictive value of abdominal fat aspiration for the diagnosis of amyloidosis. Arthritis Rheum. Jan 1989;32(1):82-5. [Medline].
• Eulitz M, Weiss DT, Solomon A. Immunoglobulin heavy-chain-associated amyloidosis. Proc Natl Acad Sci U S A. Sep 1990;87(17):6542-6. [Medline].
• Gallo G, Wisniewski T, Choi-Miura NH. Potential role of apolipoprotein-E in fibrillogenesis. Am J Pathol. Sep 1994;145(3):526-30. [Medline].
• Gebre-Medhin S, Olofsson C, Mulder H. Islet amyloid polypeptide in the islets of Langerhans: friend or foe?. Diabetologia. Jun 2000;43(6):687-95. [Medline].
• Gertz MA, Lacy MQ, Dispenzieri A. Amyloidosis: recognition, confirmation, prognosis, and therapy. Mayo Clin Proc. May 1999;74(5):490-4. [Medline].
• Granel B, Valleix S, Serratrice J. Lysozyme amyloidosis: report of 4 cases and a review of the literature. Medicine (Baltimore). Jan 2006;85(1):66-73.
• Haggqvist B, Naslund J, Sletten K. Medin: an integral fragment of aortic smooth muscle cell-produced lactadherin forms the most common human amyloid. Proc Natl Acad Sci U S A. Jul 20 1999;96(15):8669-74. [Medline].
• Hawkins PN, Pepys MB. Imaging amyloidosis with radiolabelled SAP. Eur J Nucl Med. Jul 1995;22(7):595-9. [Medline].
• Hawkins PN, Lavender JP, Pepys MB. Evaluation of systemic amyloidosis by scintigraphy with 123I-labeled serum amyloid P component. N Engl J Med. Aug 23 1990;323(8):508-13. [Medline].
• Huilgol SC, Ramnarain N, Carrington P. Cytokeratins in primary cutaneous amyloidosis. Australas J Dermatol. May 1998;39(2):81-5. [Medline].
• Jacobson DR, Pastore RD, Yaghoubian R. Variant-sequence transthyretin (isoleucine 122) in late-onset cardiac amyloidosis in black Americans. N Engl J Med. Feb 13 1997;336(7):466-73. [Medline].
• Jacobson DR, Buxbaum JN. Genetic aspects of amyloidosis. Adv Hum Genet. 1991;20:69-123, 309-11. [Medline].
• Karlsson E. IAPP as a regulator of glucose homeostasis and pancreatic hormone secretion (review). Int J Mol Med. Jun 1999;3(6):577-84. [Medline].
• Kisilevsky R. The relation of proteoglycans, serum amyloid P and apo E to amyloidosis current status, 2000. Amyloid. Mar 2000;7(1):23-5. [Medline].
• Kisilevsky R. Review: amyloidogenesis-unquestioned answers and unanswered questions. J Struct Biol. Jun 2000;130(2-3):99-108. [Medline].
• Kiuru S, Salonen O, Haltia M. Gelsolin-related spinal and cerebral amyloid angiopathy. Ann Neurol. Mar 1999;45(3):305-11. [Medline].
• Kiuru S. Gelsolin-related familial amyloidosis, Finnish type (FAF), and its variants found worldwide. Amyloid. Mar 1998;5(1):55-66. [Medline].
• Klintworth GK, Valnickova Z, Kielar RA. Familial subepithelial corneal amyloidosis--a lactoferrin-related amyloidosis. Invest Ophthalmol Vis Sci. Dec 1997;38(13):2756-63. [Medline].
• Korvatska E, Munier FL, Chaubert P. On the role of kerato-epithelin in the pathogenesis of 5q31-linked corneal dystrophies. Invest Ophthalmol Vis Sci. Sep 1999;40(10):2213-9. [Medline].
• Libbey CA, Skinner M, Cohen AS. Use of abdominal fat tissue aspirate in the diagnosis of systemic amyloidosis. Arch Intern Med. Aug 1983;143(8):1549-52. [Medline].
• Lie JT, Hammond PI. Pathology of the senescent heart: anatomic observations on 237 autopsy studies of patients 90 to 105 years old. Mayo Clin Proc. Jun 1988;63(6):552-64. [Medline].
• Looi LM. Isolated atrial amyloidosis: a clinicopathologic study indicating increased prevalence in chronic heart disease. Hum Pathol. Jun 1993;24(6):602-7. [Medline].
• Olafsson I, Grubb A. Hereditary cystatin C amyloid angiopathy. Amyloid. Mar 2000;7(1):70-9. [Medline].
• Pepys MB. Amyloidosis. Annu Rev Med. 2006;57:223-41.
• Rostagno A, Tomidokoro Y, Lashley T. Chromosome 13 dementias. Cell Mol Life Sci. Aug 2005;62(16):1814-25.
• Saad MF, Ordonez NG, Rashid RK. Medullary carcinoma of the thyroid. A study of the clinical features and prognostic factors in 161 patients. Medicine (Baltimore). Nov 1984;63(6):319-42. [Medline].
• Sandgren O. Ocular amyloidosis, with special reference to the hereditary forms with vitreous involvement. Surv Ophthalmol. Nov-Dec 1995;40(3):173-96. [Medline].
• Saraiva MJ. Transthyretin mutations in health and disease. Hum Mutat. 1995;5(3):191-6. [Medline].
• Skinner M, Sanchorawala V, Seldin DC. High-dose melphalan and autologous stem-cell transplantation in patients with AL amyloidosis: an 8-year study. Ann Intern Med. Jan 20 2004;140(2):85-93.
• Sole Arques M, Campistol JM, Munoz-Gomez J. Abdominal fat aspiration biopsy in dialysis-related amyloidosis. Arch Intern Med. Apr 1988;148(4):988. [Medline].
• Vetrivel KS, Thinakaran G. Amyloidogenic processing of beta-amyloid precursor protein in intracellular compartments. Neurology. Jan 24 2006;66(2 Suppl 1):S69-73.
• Westermark P, Araki S, Benson MD. Nomenclature of amyloid fibril proteins. Report from the meeting of the International Nomenclature Committee on Amyloidosis, August 8-9, 1998. Part 1. Amyloid. Mar 1999;6(1):63-6. [Medline].
• Westermark P, Eriksson L, Engstrom U. Prolactin-derived amyloid in the aging pituitary gland. Am J Pathol. Jan 1997;150(1):67-73. [Medline].
• Wisniewski T, Aucouturier P, Soto C. The prionoses and other conformational disorders. Amyloid. Sep 1998;5(3):212-24. [Medline].
• Yazaki M, Liepnieks JJ, Yamashita T. Renal amyloidosis caused by a novel stop-codon mutation in the apolipoprotein A-II gene. Kidney Int. Nov 2001;60(5):1658-65. [Medline].

Article Last Updated: Aug 11, 2006