Multiple Myeloma and Prostate Cancer

Question 1

Multiple Myeloma (MM)

Answer 1

• Neoplastic proliferation of plasma cells producing a monoclonal immunoglobulin malginant disease of plasma cells in bone marrow
  
  • Plasma cells proliferate in the bone marrow and often results in extensive skeletal destruction with osteolytic lesions, osteopenia, and/or pathologic fractions

Question 2

Monoclonal Antibodies

Answer 2

• Antibodies made by identical immune cells that are clones of a unique parent cell

Question 3

When is a diagnosis of MM suspected?

Answer 3

Suspected when there is one or more of the following:

• Bone pain with lytic lesions discovered on routine skeletal films or other imaging modalities
• An increased total serum protein concentration and/or presence of a monoclonal protein in urine or serum
• Systemic signs of symptoms suggestive of malignancy, such as unexplained anemia
• Hypercalemia - either symptomatically or incidentally discovered
• Acute renal failure with a bland urinalysis or rarely the nephrotic syndrome due to concurrent immunoglobulin light chain (AL) amyloidosis

Question 4

Epidemiology MM

Answer 4

• Accounts for 1-2% of all cancers and slightly more than 17% of hematogolic malignancies
• Higher incidence in African Americans
• Occurs more often in older adults - median age of diagnosis is 66years
• Familial component - risk of developing MM is 3.7X higher in those that have a frist degree relative with MM

Question 5

Clinical Presentation of MM

Answer 5

Most signs and symptoms are related to infiltration of plasma cells into bone or other organs or kidney damage from excess light chains.

• Anemia
• Bone pain - esp. back and chest
• Elevated creatinine - mainly due to light cast nephropathy or hypercalcemia
• Fatigue/generalized weakness
• Hypercalcemia
• Weight loss
• Infection
• Neuroligc disease - radiculopathy (pinched nerve), cord compression, peripheral neuropathy, CNS involvement

Question 6

Pathogenesis of MM

Answer 6

• Pathogenesis of MM is a complex process leading to the replication of a malignant clone of plasma cell origin.
• Almost all cases of MM are produced by a premalinant plasma cell proliferative disorders known as monoclonal gammopathy of undetermined signifcance (MGUS).
• Pathogenesis of MM can be thought of as a 2-step process:
  
  1. Establishment of MGUS
  2. Progression of MGUS to MM

Question 7

Establishment of MGUS

Answer 7

• Appears to develop as the result of cytogenic abnormalities, which are thought to be the product of an abnormal plasma cell response to antigenic stimulation. Results in plasma cell clone producing monoclonal immunoglobulin.
• Risk factors: older age, immunosuppresssion, environmental exposure, genetic predisposition/
• Cytogenic abnormalities - translocation events involving the immunoglobulin heavy chain (likely occurs during class switiching) results in oncogene next to a promoter region; or a genetic instability manifested by trisomies resulting in overexpression of genes that promote growth.

Question 8

Progession of MGUS to MM

Answer 8

• Further insults to the plasma cell clone, either through additional genetic abnormalities or changes in the bone marrow microenvironment, result in progression of MGUS to MM.
• Progression is thought to be due to a “random second hit”
  
  • Additional genetic changes
  • Increased cell proliferation due to cell cycle dysegulation
  • Evasion of programmed cell death
  • Changes in bone marrow microenvironment

Question 9

Abnormal Plasma Cells in MM

Answer 9

In the bone marrow some hematopoietic stems cells will differentiate into plasma cells

• Normally, bone marrow contains <5% plasma cells which secrete antibodies
• In MM, the hematopoietic stem cell shifts its production to produce more plasma cells (>10% plasma cells in bone marrow). Futhermore, these plasma cells secrete abnormal antibodies in a majority of MM cases (ex. heavy chains + light chains, light chains alone, or niether). The abnormal proteins produced and secreted by the malignant plasma cells can be detected by protein electrophoresis.

Question 10

End Organ Damage in MM

Answer 10

• Osteolytic bone lesions, hypercalcemia, bone pain, pathologic fractures - Increased RANKL produced by plasma cells and decrease in OPG results in increased osteoclast activity (bone breakdown) and decrease osteoblast activity (bone buildup).
• Renal insufficency - accumulation of Ig light chains in the tubules of the kidney results in blockage of tubules by light chain casts.
• Anemia - Due to replacement of normal hematopoietic tissue by tumours and by disruption of bone marrow microenvironment.

Question 11

Laboratory Studies MM

Answer 11

• Urinalysis - Findings in MM depend on the etiology of the kindey damage:
  
  • Myeloma cast nephropathy - presence of large, waxy, laminated casts in distal and collecting tubules. Casts are mainly make up of precipitated monoclonal light chains. Urine dipstick is typically negative for protein, since most of the proteinuria is comprise of urinary monoclonal protein rather than albumin.
  • Patients may also present with amyloidosis, these patients would be positive on dipstick.
• Peripheral smear
  
  • Rouleaux formation (RBCs take on appearance of a stack of coins in diluted suspensions of blood), leukopenia, and thrombocytopenia. Rarely able to detect monoclonal plasma cells on peripheral smear.
• Bone marrow
  
  • Bone marrow aspirate and biopsy are key in MM diagnosis
  • Bone marrow contains >10% clonal plasma cells
• Free light chain assay
  
  • Measures kappa and lambda light immunoglobulin chains that are unbound to heavy chains in the serum. In MM you may see excess production of one type of light chain
• Serum Protein electrophoresis
  
  • Will see a large gamma spike in the gamma region indicating a clonal population of Igs.
• Imaging
  
  • Cross-sectional imaging is preferred as they are more sensitive than plain radiogrpahs for detection of most skeletal lesion in myeloma
    
    • MRI is most sensitive for bone involvement
    • PET/CT is more sensitive for extramedullary involvement

Question 12

Diagnostic Criteria MM

Answer 12

• Diagnosis requries fulfillment of the following:
  
  • Clonal bone marrow plasma cells ≥ 10% or biopsy - proven boney or soft tissue plasmacytoma
• Plus ONE of the following:
  
  • Presence of related organ or tissue impairment - Increased Calicum level; Renal insufficiency; Anemia; and Bone lesions
  • Presence of a biomarker associated with near inevitable progression to end-organ damage: ≥ 60% clonal plasam cells in the bone marrow; involved/uninvolved FLC ratio of 100 or more (presence of light chains); or MRI with more than one focal lesions

Question 13

Treatment MM

Answer 13

MM is incurable

• Induction therapy
  
  • Patients eligible for HCT receive induction therapy for 2-4 months prior to stem cells collection to reduce number of tumour cells
  • Patients ineligible for HCT generally continue treatment until progression
• Maintenance
  
  • All patients will eventually relapse. Maintenance therapy prolongs progessions - free survival but unclear if it improves overall survival

Question 14

Proteasome inhibitors

Answer 14

• Proteasome - small protein complexes in cells which degrade unneeded or damaged proteins by porteolysis. Once these proteins are broken up the cell can use them to make new proteins.
  
  • Cancerous plasma cells make much larger amounts of ineffective proteins. Proteasome inhibitors work by preventing the “protein recycling process” allowing the proteins to build up in the cell. The cell then dies of build-up of accumulated wasts.
  • Overall, proteasome inhibitors have shown efficicant in both front-lin and relapse setting, but the development of resistence and side effects like peripheral neuropathy can limit its use. However, newer version are effective at lower doses can have lower incidence of neuropathy.

Question 15

Bisphosophates and Cancer

Answer 15

• Bisphosophates bind avidly to bone and are ingested by osteoclasts, resulting in inhibition of osteoclast-mediated bone resorption
• Certain cancers (breast, lung, prostate, MM) are prone to the development of bone disease. Once the tumour is in the bone marrow they alter the function of osteoclasts and osteoblsts to enhance bone resportion and inhibit bone formation, leading to skeletal destruction (cord compression, hypercalcemia, loss of mobility).
• Due to antiresorptive acitivty, bisphophonates are used in the treatment of malginant bone disease to prevent or delay skeletal morbidty associated with bone mets.
  
  • Frist generation - induce osteoclast apoptosis
  • Second and third generation - suppress osteoclast mediated bone resorption.

Question 16

Prostate Cancer

Answer 16

• One of the most common cancers in males
• Can range from microscope, well-differentiated tumour that may never be clinicall significant, to an aggressive, high grade cancer that causes metastases, morbidity, and death

Question 17

Prostate cancer screening

Answer 17

• PSA
  
  • Prostate specific antigen - a protein made solely by prostate cells (antigen is highly specific for the prostate). However, it is not specific to prostate cancer and other conditions such as BPH and prostatitis can affect PSA levels
• DRE
  
  • Asymmetric areas of induration or frank nodules are suggestive of prostate cancer. Whereas symmetric enlargement and firmness of the prostate are more frequent in men with BPH
    
    • A prostate biopsy is indicated in men with suspicous DRE, regardless of PSA
    • 25-35% of prostate cancers are not palpable on DRE

Question 18

Symptoms Prostate Cancer

Answer 18

• Men with early stage prostate cancer are asymptomatic
• Urinary frequency, urgency, nocturia, and hestiancy are seen commonly, but usually due to concomitant benign prostate enlargement
• Hematuria and hematospermia are uncommon presentations, but should prompt consideration of prostate cancer in older men
• Bone pain may be present in those with metastatic disease

Question 19

Diagnosis of prostate cancer

Answer 19

• Men with abnormal PSA and/or DRE should undergo prostate biopsy
• A negative biopsy does not exclude diagnosis of prostate cancer. Repeat biopsy may be indicated if PSA levels continue to rise

Question 20

Staging Prostate Cancer

Answer 20

• Clinical T stage - based on results of DRE, biopsy findings, and imaging studies
  
  • T4 - Tumours are fixed to or invade adjacent structures
  • T3 - lesions extend through prostatic capsule
  • T2 - lesions are palpable, but appear to be confined to the prostate
  • T1 - lesions are not palpable
• Node
  
  • N0 - no nodal involvement
  • N1 - nodal involvement
• Metastasis
  
  • Indicates presence of distant metastasis

Question 21

Evaluation of distant metastasis Prostate Cancer

Answer 21

• Prostate cancer preferentially metastasized to bone and early involvement of other sites is uncommon (tend to be osteoblastic lesions)
  
  • Bone scan - preferrd technique for identifying bone mets in prostate cancer. Only recommended for symptomatic patients.

Question 22

Treatment of Prostate Cancer

Low and very low-risk clinically localized prostate cancer

Answer 22

• Active surveillance = postponement of immediate definitive therapy, with curative-intent treatment instituted if there is clinical evidence of disease progression. This is an appropriate option for patients with small, low-grade, prostate cancers with low-risk of progression and a life expectancy of <20years. Goal is to avoid treatment complications in those where the cancer is unlikely to progress.
• Radiation therapy = can use both external beam or brachytherapy
  
  • Complications - GI symptoms, ED, urinary symptoms
• Radical prostatecomy = removal of prostate tissue.
  
  • urinary incontenence, ED
• Prognosis - radiation therapy and radical prostateconmy all provide biochemical relapse free survival of >80% and >95% remain free of local recurrance and distant metastases.

Question 23

Treatment of Prostate Cancer

Regionally localized intermediate high and very high risk prostate cancer

Answer 23

• Radiation therapy - Radiatio can be administered vua external beam, brachytherapy, or both. Generally given in conjuction with androgen deprivation therapy (ADT) in intermediate and high-risk (regionally localized).
• Radical Prostatectomy - For otherwise healthy men, radical prostatectomy is an option of men with intermediate or high risk regionally localized prostate cancer and for those withlocally advanced disease without tumour fixation to adjacent structures and without lymph node involvement.
  
  • Neoadjuvant ADT may decrease tumour volume and improve rate of complete resection.
• Lymph node involvement
  
  • Radiation therapy including the whole pelivs + ADT
  • Radical prostatectomy + ADT

Question 24

Hormone therapy for prostate cancer

Answer 24

• Androgen deprivation therapy (ADT) - goal is to reduce levels of androgens in the body as androgens stimulate prostate cancer cells to grow. Lowering androgen levels or stopping them from getting into prostate cancer cells often makes prostate cancers shrink or grow more slowly
• Hormone therapy alone does not cure prostate cancer and is generally used in the following situations:
  
  • If cancer has spread too far to be cured by surgery or radiation
  • If cancer remains or comes back after treatment with surgery or radiation
  • In conjuction with radiation therapy as initial treatmetn if you are at higher risk of recurrance
  • Before radiation to try to shrink the cancer

Question 25

Types of Hormone Therapy

Answer 25

• Treatment to lower androgen levels:
  
  • Orchiectomy (surgical castration) - removal of the testicles as a way to lower androgens
  • GnRH agonists (medical castration) - lowers amount of testosterone made by the testicles via effects on the hypothalamic pituitary axis (GnRH suppresses luteinizing hormone production and therefore synthesis of testicular androgen).
• Treatments that stop androgens from working
  
  • Anti-androgens - block androgen receptors. Generally used with orchiectomy ot GnRH agonists if they stop working when used alone.

Question 26

Castration Resistant Prostate Cancer

Answer 26

• Patients who have evidence of disease progression (increase in PSA, new mets, progression of existing mets) while being managed with ADT . I.e., cancer is stil gorwing even when testosterone levels are as low as what would be expeted if testicles were removed.
  
  • ADT is generally continued in conjunction with secondary therapies (ex. taxane chemotherapy)

Question 27

Spinal Cord Compression

Answer 27

• Compression of the dural sac and its contents by a tumour
• Seen in 5-10% of cancer patients - usually lung, breast, or prostate cancer
• Signs and symptoms:
  
  • Back pain - progressive back pain in cancer patients is spinal cord compression until proven otherwise
    
    • Pain depends on the site of compression:
      
      • Cervival - subscapsular pain
      • Thoracic - lumbosacral or hip pain
      • Lumbosacral - thoracic pain
  • Motor weakness, sensory impairment and autonomic dysfunction - compression of the nerves in the respective region causing weakness and loss of sensation
  • Ataxia - lack of voluntary coordination of muscle movement
  • Cadua equina syndrome - compression of sacral nerves that control certain functions - urinary retention, fecal incontience
• Investigations - urgent MRI with contrast
• Treatment
  
  • Prompt initiation of steroids
  • Radiation therapy or surgery + radiation therapy
• Prognosis - median survival only 3 months after coming in with spinal cord compression. Treatment is palliative.

Question 28

Superior Vena Cava (SVC) Syndrome

Answer 28

• SVCO - direct compression of the SVC by primary malignancies as well as metastatic tumours (SVC returns blood from upper extremities, head and neck veins, and sinuses).
  
  • Direct compression leads to elevaaation venous pressures causing edema.
• SVCO is caused by malignancy 65% of the time. Most commonly caused by right-sided lung cancer, and lymphoma.
• Presentation - dyspnea; swelling of face and arms; collateral dilation on chest; mass in the right chest; pre-syncope or syncope (reduction of CO due to lack of compensation).
• Investigations - CXR or CT; tissue biopsy is needed before treatment.
• Treatment (appropriate diagnosis and management can be curative).
  
  • Chemotherapy - esp if non-Hodgkins lymphoma or SCLC
  • Stent - most rapid palliation and effective in 95% of cases
  • Radiation