|Other names||Plasma cell myeloma, myelomatosis, Kahler's disease|
|Micrograph of a plasmacytoma, H&E stain|
|Specialty||Hematology and oncology|
|Symptoms||Bone pain, bleeding, frequent infections, anemia|
|Complications||Amyloidosis, kidney problems, bone fractures, overly thick blood|
|Diagnostic method||Blood or urine tests, bone marrow biopsy, medical imaging|
|Treatment||Steroids, chemotherapy, thalidomide, stem cell transplant, bisphosphonates, radiation therapy|
|Prognosis||Five-year survival rate 52% / life expectancy 6 years (USA)|
|Frequency||488,200 (affected during 2015)|
Multiple myeloma (MM), also known as plasma cell myeloma, is a cancer of plasma cells, a type of white blood cell that normally produces antibodies. Often, no symptoms are noticed initially. As it progresses, bone pain, bleeding, frequent infections, and anemia may occur. Complications may include amyloidosis.
The cause of multiple myeloma is unknown. Risk factors include obesity, radiation exposure, family history, and certain chemicals. Multiple myeloma may develop from monoclonal gammopathy of undetermined significance that progresses to smoldering multiple myeloma. The abnormal plasma cells produce abnormal antibodies, which can cause kidney problems and overly thick blood. The plasma cells can also form a mass in the bone marrow or soft tissue. When one tumor is present, it is called a plasmacytoma; more than one is called multiple myeloma. Multiple myeloma is diagnosed based on blood or urine tests finding abnormal antibodies, bone marrow biopsy finding cancerous plasma cells, and medical imaging finding bone lesions. Another common finding is high blood calcium levels.
Multiple myeloma is considered treatable, but generally incurable. Remissions may be brought about with steroids, chemotherapy, targeted therapy, and stem cell transplant. Bisphosphonates and radiation therapy are sometimes used to reduce pain from bone lesions.
Globally, multiple myeloma affected 488,000 people and resulted in 101,100 deaths in 2015. In the United States, it develops in 6.5 per 100,000 people per year and 0.7% of people are affected at some point in their lives. It usually occurs around the age of 60 and is more common in men than women. It is uncommon before the age of 40. Without treatment, typical survival is seven months. With current treatments, survival is usually 4–5 years. The five-year survival rate is about 49%. The word myeloma is from the Greek myelo- meaning "marrow" and -oma meaning "tumor".
- 1 Signs and symptoms
- 2 Cause
- 3 Pathophysiology
- 4 Diagnosis
- 5 Prevention
- 6 Treatment
- 7 Prognosis
- 8 Epidemiology
- 9 Other animals
- 10 See also
- 11 References
- 12 External links
Signs and symptoms
Because many organs can be affected by myeloma, the symptoms and signs vary greatly. A mnemonic sometimes used to remember some of the common symptoms of multiple myeloma is CRAB: C = calcium (elevated), R = renal failure, A = anemia, B = bone lesions. Myeloma has many other possible symptoms, including opportunistic infections (e.g., pneumonia) and weight loss.
Bone pain affects almost 70% of people with multiple myeloma and is the most common symptom. Myeloma bone pain usually involves the spine and ribs, and worsens with activity. Persistent, localized pain may indicate a pathological bone fracture. Involvement of the vertebrae may lead to spinal cord compression or kyphosis. Myeloma bone disease is due to the overexpression of receptor activator for nuclear factor κ B ligand (RANKL) by bone marrow stroma. RANKL activates osteoclasts, which resorb bone. The resultant bone lesions are lytic (cause breakdown) in nature, and are best seen in plain radiographs, which may show "punched-out" resorptive lesions (including the "raindrop" appearance of the skull on radiography). The breakdown of bone also leads to the release of calcium ions into the blood, leading to hypercalcemia and its associated symptoms.
The anemia found in myeloma is usually normocytic and normochromic. It results from the replacement of normal bone marrow by infiltrating tumor cells and inhibition of normal red blood cell production (hematopoiesis) by cytokines.
Impaired kidney function
The most common cause of kidney failure in multiple myeloma is due to proteins secreted by the malignant cells. Myeloma cells produce monoclonal proteins of varying types, most commonly immunoglobulins (antibodies) and free light chains, resulting in abnormally high levels of these proteins in the blood. Depending on the size of these proteins, they may be excreted through the kidneys. Kidneys can be damaged by the effects of proteins or light chains. Increased bone resorption leads to hypercalcemia and causes nephrocalcinosis, thereby contributing to the kidney failure. Amyloidosis is a distant third in the causation. People with amyloidosis have high levels of amyloid protein that can be excreted through the kidneys and cause damage to the kidneys and other organs.
The most common infections are pneumonias and pyelonephritis. Common pneumonia pathogens include S. pneumoniae, S. aureus, and K. pneumoniae, while common pathogens causing pyelonephritis include E. coli and other Gram-negative organisms. The greatest risk period for the occurrence of infection is in the initial few months after the start of chemotherapy. The increased risk of infection is due to immune deficiency. Although the total immunoglobulin level is typically elevated in multiple myeloma, the majority of the antibodies are ineffective monoclonal antibodies from the clonal plasma cell. A selected group of people with documented hypogammaglobulinemia may benefit from replacement immunoglobulin therapy to reduce the risk of infection.
Some symptoms (e.g., weakness, confusion, and fatigue) may be due to anemia or hypercalcemia. Headache, visual changes, and retinopathy may be the result of hyperviscosity of the blood depending on the properties of the paraprotein. Finally, radicular pain, loss of bowel or bladder control (due to involvement of spinal cord leading to cord compression) or carpal tunnel syndrome, and other neuropathies (due to infiltration of peripheral nerves by amyloid) may occur. It may give rise to paraplegia in late-presenting cases.
When the disease is well-controlled, neurological symptoms may result from current treatments, some of which may cause peripheral neuropathy, manifesting itself as numbness or pain in the hands, feet, and lower legs.
The initial symptoms may involve pain, numbness, swelling, expansion of the jaw, tooth mobility, and radiolucency. Multiple myeloma in the mouth can mimic common teeth problems like periapical abscess or periodontal abscess, gingivitis, periodontitis, or other gingival enlargement or masses.
The cause of multiple myeloma is generally unknown.
- Monoclonal gammopathy of undetermined significance (MGUS) increases the risk of developing multiple myeloma. MGUS transforms to multiple myeloma at the rate of 1% to 2% per year, and almost all cases of multiple myeloma are preceded by MGUS.
- Smoldering multiple myeloma increases the risk of developing multiple myeloma. Individuals diagnosed with this premalignant disorder develop multiple myeloma at a rate of 10% per year for the first 5 years, 3% per year for the next 5 years, and then 1% per year.
- Obesity is related to multiple myeloma with each increase of body mass index by five increasing the risk by 11%.
A familial predisposition to myeloma exists. Hyperphosphorylation of a number of proteins—the paratarg proteins—a tendency that is inherited in an autosomal dominant manner, appears a common mechanism in these families. This tendency is more common in African-American with myeloma and may contribute to the higher rates of myeloma in this group.
Rarely, Epstein-Barr virus (EBV) is associated with multiple myeloma, particularly in individuals who have an immunodeficiency due to e.g. HIV/AIDS, organ transplantation, or a chronic inflammatory condition such as rheumatoid arthritis. EBV-positive multiple myeloma is classified by the World Health Organization (2016) as one form of the Epstein-Barr virus-associated lymphoproliferative diseases and termed Epstein-Barr virus-associated plasma cell myeloma. EBV-positive disease is more common in the plasmacytoma rather than multiple myeloma form of plasma cell cancer. Tissues involved in EBV+ disease typically show foci of EBV+ cells with the appearance of rapidly proliferating immature or poorly differentiated plasma cells. The cells express products of EBV genes such as EBER1 and EBER2. While the EBV contributes to the development and/or progression of most Epstein-Barr virus-associated lymphoproliferatve diseases, its role in multiple myeloma is not known. However, people who are EBV-positive with localized plasmacytoma(s) are more likely to progress to multiple myeloma compared to people with EBV-negative plasmacytoma(s). This suggest that EBV may have a role in the progression of plasmacytomas to systemic multiple myeloma.
B lymphocytes start in the bone marrow and move to the lymph nodes. As they progress, they mature and display different proteins on their cell surfaces. When they are activated to secrete antibodies, they are known as plasma cells.
Multiple myeloma develops in B lymphocytes after they have left the part of the lymph node known as the germinal center. The normal cell line most closely associated with MM cells is generally taken to be either an activated memory B cell or the precursor to plasma cells, the plasmablast.
The immune system keeps the proliferation of B cells and the secretion of antibodies under tight control. When chromosomes and genes are damaged, often through rearrangement, this control is lost. Often, a promoter gene moves (or translocates) to a chromosome, where it stimulates an antibody gene to overproduction.
A chromosomal translocation between the immunoglobulin heavy chain gene (on chromosome 14, locus q32) and an oncogene (often 11q13, 4p16.3, 6p21, 16q23 and 20q11) is frequently observed in people with multiple myeloma. This mutation results in dysregulation of the oncogene which is thought to be an important initiating event in the pathogenesis of myeloma. The result is a proliferation of a plasma cell clone and genomic instability that leads to further mutations and translocations. The chromosome 14 abnormality is observed in about 50% of all cases of myeloma. Deletion of (parts of) chromosome 13 is also observed in about 50% of cases.
Production of cytokines (especially IL-6) by the plasma cells causes much of their localised damage, such as osteoporosis, and creates a microenvironment in which the malignant cells thrive. Angiogenesis (the generation of new blood vessels) is increased.
The produced antibodies are deposited in various organs, leading to kidney failure, polyneuropathy, and various other myeloma-associated symptoms.
In a study that investigated the DNA methylation profile of multiple myeloma cells and normal plasma cells, a gradual demethylation from stem cells to plasma cells was observed. The observed methylation pattern of CpG within intronic regions with enhancer-related chromatin marks in multiple myeloma is similar to undifferentiated precursor and stem cells. These results may represent a de novo epigenetic reprogramming in multiple myeloma, leading to the acquisition of a methylation pattern related to stemness.
The genetic and epigenetic changes occur progressively. The initial change, often involving one chromosome 14 translocation, establishes a clone of bone marrow plasma cells that causes the asymptomatic disorder MGUS, which is a premalignant disorder characterized by increased numbers of plasma cells in the bone marrow or the circulation of a myeloma protein immunoglobulin. Further genetic or epigenic changes produce a new clone of bone marrow plasma cells, usually descendant from the original clone, that causes the more serious, but still asymptomatic premalignant disorder smoldering multiple myeloma. This myeloma is characterized by a rise in the number of bone marrow plasma cells or levels of the circulating myeloma protein above that seen in MGUS.
Subsequent genetic and epigenetic changes lead to a new, more aggressive clone of plasma cells, which cause further rises in the level of the circulating myeloma protein, further rises in the number of bone marrow plasma cells, or the development of one or more of a specific set of "CRAB" symptoms, which are the basis for diagnosing malignant multiple myeloma and treating the disease.
In a small percentage of multiple myeloma cases, further genetic and epigenetic changes lead to the development of a plasma cell clone that moves from the bone marrow into the circulatory system, invades distant tissues, and thereby causes the most malignant of all plasma cell dyscrasias, plasma cell leukemia. Thus, a fundamental genetic instability in plasma cells or their precursors leads to the progression:
Being asymptomatic, monoclonal gammapathy of undetermined significance and smoldering multiple myeloma are typically diagnosed fortuitously by detecting a myeloma protein on serum protein electrophoresis tests done for other purposes. MGUS is a relatively stable condition afflicting 3% of people aged 50 and 5% of people aged 70; it progresses to multiple myeloma at a rate of 0.5-1% cases per year; smoldering multiple myeloma does so at a rate of 10% per year for the first 5 years, but then falls off sharply to 3% per year for the next 5 years and thereafter to 1% per year.
Overall, some 2-4% of multiple myeloma cases eventually progress to plasma cell leukemia.
The presence of unexplained anemia, kidney dysfunction, a high erythrocyte sedimentation rate, lytic bone lesions, elevated beta-2 microglobulin, or a high serum protein (especially raised globulins or immunoglobulin) may prompt further testing.
The globulin level may be normal in established disease. A doctor may request protein electrophoresis of the blood and urine, which might show the presence of a paraprotein (monoclonal protein, or M protein) band, with or without reduction of the other (normal) immunoglobulins (known as immune paresis). One type of paraprotein is the Bence Jones protein, which is a urinary paraprotein composed of free light chains. Quantitative measurements of the paraprotein are necessary to establish a diagnosis and to monitor the disease. The paraprotein is an abnormal immunoglobulin produced by the tumor clone.
In theory, multiple myeloma can produce all classes of immunoglobulin, but IgG paraproteins are most common, followed by IgA and IgM. IgD and IgE myeloma are very rare. In addition, light and or heavy chains (the building blocks of antibodies) may be secreted in isolation: κ- or λ-light chains or any of the five types of heavy chains (α-, γ-, δ-, ε- or μ-heavy chains). People without evidence of a monoclonal protein may have "nonsecretory" myeloma (not producing immunoglobulins); this represents about 3% of all people with multiple myeloma.
Additional findings may include a raised calcium level (when osteoclasts are breaking down bone, releasing it into the bloodstream), raised serum creatinine level due to reduced kidney function, which is mainly due to casts of paraprotein deposition in the kidney, although the cast may also contain complete immunoglobulins, Tamm-Horsfall protein and albumin.
Other useful laboratory tests include quantitative measurement of IgA, IgG, and IgM to look for immune paresis, and beta-2 microglobulin, which provides prognostic information. On peripheral blood smear, the rouleaux formation of red blood cells is commonly seen, though this is not specific.
The recent introduction of a commercial immunoassay for measurement of free light chains potentially offers an improvement in monitoring disease progression and response to treatment, particularly where the paraprotein is difficult to measure accurately by electrophoresis (for example in light chain myeloma, or where the paraprotein level is very low). Initial research also suggests that measurement of free light chains may also be used, in conjunction with other markers, for assessment of the risk of progression from MGUS to multiple myeloma.
This assay, the serum free light chain assay, has recently been recommended by the International Myeloma Working Group for the screening, diagnosis, prognosis, and monitoring of plasma cell dyscrasias.
Bone marrow aspirate showing the histologic correlate of multiple myeloma under the microscope, H&E stain
A bone marrow biopsy is usually performed to estimate the percentage of bone marrow occupied by plasma cells. This percentage is used in the diagnostic criteria for myeloma. Immunohistochemistry (staining particular cell types using antibodies against surface proteins) can detect plasma cells that express immunoglobulin in the cytoplasm and occasionally on the cell surface; myeloma cells are often CD56, CD38, CD138, and CD319 positive and CD19, CD20, and CD45 negative. Flow cytometry is often used to establish the clonal nature of the plasma cells, which will generally express only kappa or lambda light chain. Cytogenetics may also be performed in myeloma for prognostic purposes, including a myeloma-specific fluorescent in situ hybridization and virtual karyotype.
The plasma cells seen in multiple myeloma have several possible morphologies. First, they could have the appearance of a normal plasma cell, a large cell two or three times the size of a peripheral lymphocyte. Because they are actively producing antibodies, the Golgi apparatus typically produces a light-colored area adjacent to the nucleus, called a perinuclear halo. The single nucleus (with inside a single nucleolus with vesicular nuclear chromatin) is eccentric, displaced by an abundant cytoplasm. Other common morphologies seen, but which are not usual in normal plasma cells, include:
- Bizarre cells, which are multinucleated
- Mott cells, containing multiple clustered cytoplasmic droplets or other inclusions (sometimes confused with auer rods, commonly seen in myeloid blasts)
- Flame cells, having a fiery red cytoplasm
Historically, the CD138 has been used to isolate myeloma cells for diagnostic purposes. However, this antigen disappears rapidly ex vivo. Recently, however, the surface antigen CD319 (SLAMF7) was discovered to be considerably more stable and allows robust isolation of malignant plasma cells from delayed or even cryopreserved samples.
The prognosis varies widely depending upon various risk factors. The Mayo Clinic has developed a risk-stratification model termed Mayo Stratification for Myeloma and Risk-adapted Therapy (mSMART), which divides people into high-risk and standard-risk categories. People with deletion of chromosome 13 or hypodiploidy by conventional cytogenetics, t(4;14), t(14;16), t(14;20) or 17p- by molecular genetic studies, or with a high plasma cell labeling index (3% or more) are considered to have high-risk myeloma.
The diagnostic examination of a person with suspected multiple myeloma typically includes a skeletal survey. This is a series of X-rays of the skull, axial skeleton, and proximal long bones. Myeloma activity sometimes appears as "lytic lesions" (with local disappearance of normal bone due to resorption), and on the skull X-ray as "punched-out lesions" (pepper-pot skull). Lesions may also be sclerotic, which is seen as radiodense. Overall, the radiodensity of myeloma is between −30 and 120 Hounsfield units (HU). Magnetic resonance imaging is more sensitive than simple X-ray in the detection of lytic lesions, and may supersede skeletal survey, especially when vertebral disease is suspected. Occasionally, a CT scan is performed to measure the size of soft-tissue plasmacytomas. Bone scans are typically not of any additional value in the workup of people with myeloma (no new bone formation; lytic lesions not well visualized on bone scan).
- Symptomatic myeloma (all three criteria must be met):
- Clonal plasma cells >10% on bone marrow biopsy or (in any quantity) in a biopsy from other tissues (plasmacytoma)
- A monoclonal protein (myeloma protein) in either serum or urine (except in cases of true nonsecretory myeloma)
- Evidence of end-organ damage felt related to the plasma cell disorder (related organ or tissue impairment, CRAB):
Note: Recurrent infections alone in a person who has none of the CRAB features is not sufficient to make the diagnosis of myeloma. People who lack CRAB features, but have evidence of amyloidosis, should be considered as amyloidosis and not myeloma. CRAB-like abnormalities are common with numerous diseases, and these abnormalities must be felt to be directly attributable to the related plasma cell disorder and every attempt made to rule out other underlying causes of anemia, kidney failure, etc.
In 2014, the IMWG updated their criteria further to include biomarkers of malignancy. These biomarkers are >60% clonal plasma cells, a serum involved / uninvolved free light chain ratio ≥ 100 (the concentration of the involved free light chain must be ≥ 100 mg/l) and more than one focal lesion ≥ 5 mm by MRI. Together, these biomarkers and the CRAB criteria are known as myeloma-defining events (MDEs). A person must have >10 % clonal plasma cells and any MDE to be diagnosed with myeloma. The biomarker criteria were added so that smouldering people with multiple myeloma at high risk of developing multiple myeloma could be diagnosed before organ damage occurred, so they would therefore have a better prognosis.
- Asymptomatic/smoldering myeloma:
- Serum M protein >30 g/l (3 g/dl) or
- Clonal plasma cells >10% on bone marrow biopsy and
- No myeloma-related organ or tissue impairment
- Monoclonal gammopathy of undetermined significance (MGUS):
- Serum paraprotein <30 g/l (3 g/dl) and
- Clonal plasma cells <10% on bone marrow biopsy and
- No myeloma-related organ or tissue impairment or a related B-cell lymphoproliferative disorder
Related conditions include solitary plasmacytoma (a single tumor of plasma cells, typically treated with irradiation), plasma cell dyscrasia (where only the antibodies produce symptoms, e.g., AL amyloidosis), and peripheral neuropathy, organomegaly, endocrinopathy, monoclonal plasma cell disorder, and skin changes.
- International staging system
- Stage I: β2 microglobulin (β2M) < 3.5 mg/l, albumin ≥ 3.5 g/dl
- Stage II: β2M < 3.5 mg/l and albumin < 3.5 g/dl; or β2M 3.5–5.5 mg/l, irrespective of the serum albumin
- Stage III: β2M ≥ 5.5 mg/l
Note that the ISS should be used only in people who meet diagnostic criteria for myeloma. People with MGUS and asymptomatic myeloma who have kidney dysfunction from unrelated causes such as diabetes or hypertension may have elevated β2M levels from the kidney dysfunction and cannot be considered as stage III myeloma. This is one of the limitations of the ISS. It does not really quantify tumor burden or extent unlike staging systems used in other cancers. It is more of a prognostic index rather than a true staging system. For this reason, the ISS is recommended to be used along with the Durie–Salmon staging system.
- Durie–Salmon staging system
First published in 1975, the Durie–Salmon staging system is still in use. However, one of the limitations of the Durie–Salmon staging system is the subjectivity in determining the extent of bone disease.
- stage I: all of
- Hb > 10 g/dl
- normal calcium
- Skeletal survey: normal or single plasmacytoma or osteoporosis
- Serum paraprotein level < 5 g/dl if IgG, < 3 g/dl if IgA
- Urinary light chain excretion < 4 g/24h
- stage II: fulfilling the criteria of neither I nor III
- stage III: one or more of
- Hb < 8.5 g/dl
- high calcium > 12 mg/dl
- Skeletal survey - three or more lytic bone lesions
- Serum paraprotein > 7 g/dl if IgG, > 5 g/dl if IgA
- Urinary light chain excretion > 12 g/24 h
Stages I, II, and III of the Durie–Salmon staging system can be divided into A or B depending on serum creatinine:
- A: serum creatinine < 2 mg/dl (< 177 μmol/l)
- B: serum creatinine > 2 mg/dl (> 177 μmol/l)
The risk of multiple myeloma can be reduced slightly by maintaining a normal body weight.
Treatment is indicated in myeloma with symptoms. If there are no symptoms, but a paraprotein typical of myeloma and a diagnostic bone marrow are present without end-organ damage, treatment is usually deferred or restricted to clinical trials. Treatment for multiple myeloma is focused on decreasing the clonal plasma cell population and consequently decrease the symptoms of disease.
Initial treatment of multiple myeloma depends on the person's age and other illnesses present.
The preferred treatment for those under the age of 65 is high-dose chemotherapy, commonly with bortezomib-based regimens, and lenalidomide–dexamethasone, to be followed by a stem cell transplant. A 2016 study concluded that stem cell transplant is the preferred treatment of multiple myeloma. There are two types of stem cell transplants to treat multiple myeloma. In autologous hematopoietic stem-cell transplantation (ASCT) – a person's own stem cells are collected from their own blood, the patient is given high-dose chemotherapy and then the patient’s stem cells are transplanted back into the person. It is not curative, but does prolong overall survival and complete remission. In allogeneic stem-cell transplantation, a healthy donor’s stem cells are transplanted into the affected person. Allogenic stem-cell transplantation has the potential for a cure, but is used in a very small percentage of people (and in the relapsed setting, not as part of initial treatment). Furthermore, a 5–10% treatment-associated mortality rate is associated with allogeneic stem-cell transplant.
People over age 65 and people with significant concurrent illnesses often cannot tolerate stem-cell transplantation. For these people, the standard of care has been chemotherapy with melphalan and prednisone. Recent studies among this population suggest improved outcomes with new chemotherapy regimens, e.g., with bortezomib. Treatment with bortezomib, melphalan, and prednisone had an estimated overall survival of 83% at 30 months, lenalidomide plus low-dose dexamethasone an 82% survival at 2 years, and melphalan, prednisone, and lenalidomide had a 90% survival at 2 years. Head-to-head studies comparing these regimens have not been performed as of 2008[update].
There is support for continuous therapies with multiple drug combinations of bortezomib, lenalidomide and thalidomide as initial treatment for transplant-ineligible multiple myeloma.
A 2009 review noted, "Deep venous thrombosis and pulmonary embolism are the major side effects of thalidomide and lenalidomide. Lenalidomide causes more myelosuppression, and thalidomide causes more sedation. Chemotherapy-induced peripheral neuropathy and thrombocytopenia are major side effects of bortezomib."
Most people, including those treated with ASCT, relapse after initial treatment. Maintenance therapy using a prolonged course of low-toxicity medications is often used to prevent relapse. A 2017 meta-analysis showed that post-ASCT maintenance therapy with lenalidomide improved progression-free survival and overall survival in people at standard risk. A 2012 clinical trial showed that people with intermediate- and high-risk disease benefit from a bortezomib-based maintenance regimen.
The natural history of myeloma is of relapse following treatment. This may be attributed to tumor heterogeneity. Depending on the person's condition, the prior treatment modalities used and the duration of remission, options for relapsed disease include retreatment with the original agent, use of other agents (such as melphalan, cyclophosphamide, thalidomide, or dexamethasone, alone or in combination), and a second ASCT.
Later in the course of the disease, it becomes refractory (resistant) to formerly effective treatment. This stage is referred to as relapsed/refractory multiple myeloma (RRMM). Treatment modalities that are commonly use to treat RRMM include dexamethasone, proteasome inhibitors (e.g. bortezomib and carfilzomib), immunomodulatory imide drugs (e.g. thalidomide, lenalidomide, and pomalidomide), and certain monoclonal antibodies (e.g. against CD38 and CD319). Survival expectancy has risen in recent years[medical citation needed], and new treatments are under development.[medical citation needed]
Kidney failure in multiple myeloma can be acute (reversible) or chronic (irreversible). Acute kidney failure typically resolves when the calcium and paraprotein levels are brought under control. Treatment of chronic kidney failure is dependent on the type of kidney failure and may involve dialysis.
Several newer options are approved for the management of advanced disease:
- ixazomib — an orally available proteasome inhibitor indicated in combination with lenalidomide and dexamethasone in people who have received at least one prior therapy
- panobinostat — an orally available histone deacetylase inhibitor used in combination with bortezomib and dexamethasone in people who have received at least two prior chemotherapy regimens, including bortezomib and an immunomodulatory agent
- carfilzomib — a proteasome inhibitor that is indicated:
- as a single agent in people who have received one or more lines of therapy
- in combination with dexamethasone or with lenalidomide and dexamethasone in people who have received one to three lines of therapy
- elotuzumab — an immunostimulatory humanized monoclonal antibody against SLAMF7 (also known as CD319) indicated in combination with lenalidomide and dexamethasone in people who have received one to three prior therapies
- daratumumab — a monoclonal antibody against CD38 indicated in people who have received at least three prior lines of therapy including a proteasome inhibitor and an immunomodulatory agent or who are double refractory to a proteasome inhibitor and an immunomodulatory agent
- selinexor — an orally available selective inhibitor of nuclear export indicated in combination with dexamethasone in people who have received at least four prior therapies and whose disease does not respond to at least two proteasome inhibitors, two immunomodulatory agents and an anti-CD38 monoclonal antibody
In addition to direct treatment of the plasma cell proliferation, bisphosphonates (e.g., pamidronate or zoledronic acid) are routinely administered to prevent fractures; they have also been observed to have a direct antitumor effect even in people without known skeletal disease. If needed, red blood cell transfusions or erythropoietin can be used for management of anemia.
Palliative care is appropriate at any stage of multiple myeloma and can be provided alongside curative treatment. In addition to addressing symptoms of cancer, palliative care helps manage unwanted side effects, such as pain and nausea related to treatments.
Oral prophylaxis, hygiene instruction and elimination of sources of infection within the mouth before beginning cancer treatment, can reduce the risk of infectious complications. Before starting bisphosphonates therapy, the person’s dental health should be evaluated to assess the risk factors to prevent the development of medication-related osteonecrosis of the jaw (MRONJ). If there are any symptoms or radiographic appearance of MRONJ like jaw pain, loose tooth, mucosal swelling, early referral to an oral surgeon is recommended. Dental extractions should be avoided during the active period of treatment and treat the tooth with nonsurgical root canal treatment instead.
With high-dose therapy followed by ASCT, the median survival has been estimated in 2003 to be about 4.5 years, compared to a median around 3.5 years with "standard" therapy. Overall the 5-year survival rate is around 35%.
The prognoses for people with multiple myeloma, as those with other diseases, are not the same for everyone. The average age of onset is 70 years. Older people are often experiencing other serious diseases, which affect survival. Younger people might have much longer survival rates.
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Some myeloma centers now employ genetic testing, which they call a “gene array” . By examining DNA, oncologists can determine if people are at high or low risk of the cancer returning quickly following treatment.
Cytogenetic analysis of myeloma cells may be of prognostic value, with deletion of chromosome 13, nonhyperdiploidy, and the balanced translocations t(4;14) and t(14;16) conferring a poorer prognosis. The 11q13 and 6p21 cytogenetic abnormalities are associated with a better prognosis.
Prognostic markers such as these are always generated by retrospective analyses, and new treatment developments likely will improve the outlook for those with traditionally "poor-risk" disease.
SNP array karyotyping can detect copy number alterations of prognostic significance that may be missed by a targeted FISH panel. In MM, lack of a proliferative clone makes conventional cytogenetics informative in only ~30% of cases.
- Virtual karyotyping identified chromosomal abnormalities in 98% of MM cases
- del(12p13.31) is an independent adverse marker
- amp(5q31.1) is a favorable marker
- The prognostic impact of amp(5q31.1) overrides that of hyperdiploidy and also identifies people who greatly benefit from high-dose therapy.
Array-based karyotyping cannot detect balanced translocations, such as t(4;14) seen in about 15% of MM. Therefore, FISH for this translocation should also be performed if using SNP arrays to detect genome-wide copy number alterations of prognostic significance in MM.
In the United States in 2016, an estimated 30,330 new cases and 12,650 deaths were reported. These numbers are based on assumptions made using data from 2011, which estimated the number of people affected as 83,367 people, the number of new cases as 6.1 per 100,000 people per year, and the mortality as 3.4 per 100,000 people per year.
Multiple myeloma affects slightly more men than women. African Americans and native Pacific Islanders have the highest reported number of new cases of this disease in the United States and Asians the lowest. Results of one study found the number of new cases of myeloma to be 9.5 cases per 100,000 African Americans and 4.1 cases per 100,000 Caucasian Americans. Among African Americans, myeloma is one of the top-10 causes of cancer death.
Myeloma is the 17th-most common cancer in the UK: around 4,800 people were diagnosed with the disease in 2011. It is the 16th-most common cause of cancer death: around 2,700 people died of it in 2012.
In dogs, multiple myeloma accounts for around 8% of all haemopoietic tumors. Multiple myeloma occurs in older dogs, and is not particularly associated with either males or females. No breeds appear overrepresented in case reviews that have been conducted. Diagnosis in dogs is usually delayed due to the initial nonspecificity and range of clinical signs possible. Diagnosis usually involves bone-marrow studies, X-rays, and plasma-protein studies. In dogs, protein studies usually reveal the monoclonal gammaglobulin elevation to be IgA or IgG in equal number of cases. In rare cases the globulin elevation is IgM, which is referred to as Waldenström's macroglobulinemia. The prognosis for initial control and return to good quality of life in dogs is good; 43% of dogs started on a combination chemotherapeutic protocol achieved complete remission. Long-term survival is normal, with a median of 540 days reported. The disease eventually recurs, becoming resistant to available therapies. The complications of kidney failure, sepsis, or pain can lead to an animal's death, frequently by euthanasia.
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