Prostate Cancer: Diagnosis and evaluation: Difference between revisions

See 2023 AUA Guidelines on Early Detection of Prostate Cancer

Includes 2021 CUA Best Practice Report on PET/CT and PET/MR in Prostate Cancer

Clinical Presentation of Prostate Cancer[edit | edit source]

• Only GU malignancy diagnosed by screening
  • Kidney cancer usually detected incidentally on imaging
  • Bladder cancer usually presents with hematuria
• At the time of diagnosis§
  • ≈80% present with localized disease
  • ≈12% present with regional disease
  • 5% present with metastatic disease
    • The proportion of patients presenting with metastatic disease has decreased over time, partly due to PSA screening

Diagnosis and Evaluation[edit | edit source]

UrologySchool.com Summary[edit | edit source]

• History and Physical Exam
• Labs
  • PSA
• Imaging
  • MRI
• Other
  • Prostate biopsy
    • If suspicion for clinically significant prostate cancer (based on history, physical exam, PSA, and MRI) and diagnosis will influence management.

History and physical exam[edit | edit source]

• History
  1. Signs and symptoms of prostate cancer
     • Localized disease is usually asymptomatic
     • Advanced disease may be associated with signs and symptoms
       • Regional symptoms: lower urinary tract symptoms, hematuria, hematospermia, bladder outlet obstruction causing renal failure, decreased ejaculate volume, and rarely, impotence
       • Metastatic symptoms: bone pain, lethargy, anemia, weight loss, pathologic fractures, and lower extremity edema; less common are malignant retroperitoneal fibrosis, paraneoplastic syndromes, disseminated intravascular coagulation, and paralysis
  2. Risk factors for prostate cancer
  3. Eligibility for investigations/treatment
     • PMHx, FHx, Meds, All, Social, etc.
       • Will patient benefit from investigations/treatment (age, competing risk (comorbidity))?
         • Is a TRUS biopsy of benefit in a 95 year-old male with a PSA 400 ng/mL ?
       • Is the patient a candidate for treatment (contraindications to radiotherapy, for example)?
       • Family history
         • Criteria for "strong" family history (2):
           1. ≥1 brother or father OR ≥2 male relatives with one of the following (3):
              1. Diagnosed with prostate cancer at age <60 years
              2. Any of whom died of prostate cancer
              3. Any of whom had metastatic prostate cancer.
           2. Family history of other cancers with ≥2 cancers in hereditary breast and ovarian cancer syndrome or Lynch syndrome spectrum.
              • Hereditary breast and ovarian cancer syndrome
                • Associated cancers (5):[1]
                1. Breast (male and female)
                2. Ovarian
                3. Prostate
                4. Pancreatic
                5. Melanoma
              • Lynch syndrome
                • Associated cancers (11)[2]
                  1. Colorectal (20-80%) (most common)
                  2. Gynecologic
                     1. Endometrial (15-60%) in females (second most common)
                     2. Ovarian cancer (1-38%) in females
                  3. Urologic
                     1. Urothelial (1-18%), includes upper urinary tract and bladder
                     2. Prostate
                     3. Adrenal§
                  4. Other gastrointestinal
                     1. Gastric cancers (1-13%)
                     2. Hepatobiliary
                     3. Small bowel
                  5. Skin
                     • Sebaceous adenoma, sebaceous epithelioma, sebaceous adenocarcinoma, keratoacanthoma, and squamous cell carcinoma[3]
                  6. Brain
                  7. Inconsistent: Pancreas, breast, (prostate)
       • Patients with a "strong" family history should ideally be genotyped[4]
         • Genotype is to ascertain whether there is presence of a pathogenic variant (e.g., BRCA1/2, Lynch Syndrome, ATM, CHEK2) or one or more of a growing set of identified germline DNA damage-repair mutations found in patients with metastatic prostate cancer diagnoses.
  4. Patient preference for investigations/treatment
     • Benefits/harms of treatment (sexual function, for example)
• Physical exam
  • Body habitus
    • Determine candidacy for intervention
  • Digital rectal examination
    • A palpable tumour and the extent is associated with local disease extent (clinical T stage)
      • Can both overestimate and underestimate the extent of disease because of its poor sensitivity and lack of reproducibility
        • Consider useful to detect presence, but not useful to assess stage
    • In a screened population, an abnormal DRE is associated with an increased risk for detecting high-grade (Gleason 8 to 10) prostate cancer
    • Indications (2023 AUA Guidelines on Early Detection of Prostate Cancer[5])
      • Screening
        • Should not use DRE as the sole screening method.
          • The primary screening modality recommended for the early detection of prostate cancer is a PSA blood test.
        • Insufficient evidence to support adding DRE to PSA-based prostate cancer screening.
          • For various reasons, clinicians may choose to complement PSA screening with DRE based on SDM.
            • When DRE and PSA tests are used in prostate cancer screening, detection rates are higher with PSA testing alone vs. DRE alone, and highest with the tests together[6]
        • 2018 AUA and 2017 CUA Guidelines support the role of DRE in screening
      • Elevated PSA[7]
        • If PSA ≥ 2 ng/mL, strongly consider supplementary DRE to establish risk of clinically significant prostate cancer.
          • Highest utility of DRE in randomized trials is demonstrated in the workup of patients with an elevated PSA.*******In contrast to a screening application, use of DRE subsequent to the screening encounter may be of value.
            • • In patients undergoing prostate biopsy for an elevated PSA during screening, abnormal DRE improves the PPV for any prostate cancer and GG2+ detection

Labs[edit | edit source]

PSA[8][edit | edit source]

• Serum PSA is the single test with the highest positive predictive value for prostate cancer
  • Although as many as 20-30% of males evaluated for an elevated PSA level may be diagnosed with prostate cancer after TRUS biopsy, as many as 70-80% will not be found to have cancer
• If newly elevated PSA (no prior PSA or current value inconsistent with previous trend), then repeat the PSA prior to a secondary biomarker, imaging, or biopsy.
  • In people with a newly elevated PSA, it will return to a normal level in 25-40% upon retesting.
  • Half-life: 2-3 days[9][10]
  • A repeat PSA in a few months is recommended, though it can be shortened or lengthened depending on other clinical factors.

Causes of elevated PSA[edit | edit source]

1. Prostate disease (BPH, prostatitis, prostate cancer, etc.)
2. Prostate manipulation (prostate massage, biopsy, etc.)

• Prostate Disease
  • Prostate cancer
    • Prostate cancer cells produce less PSA than normal prostatic tissue
    • PSA becomes elevated in prostate cancer due to disruption of cellular architecture within the prostate gland
      • Prostate cancer lacks basal cells, resulting in the disruption of the basement membrane and normal lumen architecture
    • PSA levels are inversely correlated with risks of
      • Pathologically organ-confined (pT2) disease
        • PSA < 4.0 ng/mL: 80%
        • PSA 4-10 ng/mL: 66%
        • PSA > 10.0 ng/mL: <50%
      • Pelvic lymph node involvement
        • PSA >20 ng/ml: 20%
        • PSA >50 ng/mL: 75%
• Prostate manipulation
  • May influence PSA in a clinically meaningful way[11]
    1. Urinary tract infections
    2. Instrumentation (e.g., prostate biopsy, cystoscopy, urinary retention, recent bladder catheterization)
       1. Biopsy[12][13]
          • Results in immediate elevation in the serum PSA level, with a median increase of 6-8 ng/mL
          • Usually returns to a stable, baseline level within 2-3 weeks
       2. Cystoscopy[14][15]
          • Studies have found that cystoscopy results in small (0.05-0.15 ng/mL) increase in PSA and have suggested that serum PSA determination after either a flexible or a rigid cystoscopy is accurate and reliable
       3. TURP[16][17]
          • Results in immediate elevation in the serum PSA level, with a median increase of 6-13 ng/mL[18]
          • Usually returns to a stable, baseline level within 2-3 weeks[19]
       4. Recent bladder catheterization
          • One study found very little effect on PSA level at day 1 and 3 after catheterization and suggested that routine evaluation PSA in patients with recent catheterization.[20]
  • Unlikely to influence PSA in a clinically meaningful way[21]
    1. DRE
       • Can lead to slight increases in serum PSA level; however, the resultant change in PSA values falls within the error of the assay and rarely causes false-positive test results
    2. Bicycle riding
       • With long-distance (> 55km) bicycle rides, PSA levels increasing by ≈10%
    3. Ejaculation
       • Studies examining the effect of ejaculation on serum PSA have reported conflicting results.
         • Most controlled studies evaluating ejaculation suggest it either does not significantly impact or modestly increases (~10%) PSA.
       • A repeat PSA test after 48 hours of sexual abstinence may be helpful for interpreting serum PSA levels that are minimally elevated or newly elevated.
    4. TRUS[22]
       • Results in small (0.3 ng/mL) increase in PSA
       • Serum PSA determination after TRUS without biopsy is accurate and reliable
  • Most of the rise in total PSA after prostate manipulation is contributed by the free (non-bound) component.
    • In general, complexed PSA is the most stable component and relatively little rise occurs following prostate manipulation.

Clinical factors that influence PSA[edit | edit source]

• In the absence of prostate cancer, PSA levels vary with (4):
  1. Age
  2. Race
     • African-American males without prostate cancer have higher PSA values than Caucasians
  3. Prostate volume
     • PSA increases 4%/mL prostate volume
       • BPH surgery can lead to reductions in the serum PSA level
       • Annual rate of change in PSA is higher in men with BPH compared to men without BPH
  4. BMI
     • Increasing BMI independently associated with decreasing serum PSA

PSA-derivatives[edit | edit source]

• Concept is to adjust for known factors that can influence PSA (age, volume, race (BMI can also influence PSA)) and improve specificity
  • Patients with prostate cancer may have a “normal” PSA (i.e. false-negative) and patients without prostate cancer may have "elevated" PSA (i.e. false-positive); PSA is neither sensitive nor specific, particularly between 4.0-10.0 ng/dL.

Volume-adjusted PSA[edit | edit source]

• Concept is to reduce confounding from BPH
• Includes PSA divided by prostate volume (PSA density, PSAD), complexed PSAD (cPSA divided by prostate volume), and PSA transition zone density (PSA divided by transition zone volume, PSAT)
  • A PSAD of ≥0.15 has been proposed for recommending prostate biopsy in men with PSA levels between 4-10 ng/mL and normal DRE
  • PSAT has been developed to adjust for the transition zone volume, the major determinant of serum PSA in men without prostate cancer
• Prostate volume typically determined by US

Age-/race- adjusted PSA[edit | edit source]

• Race: African-American men without prostate cancer have higher PSA values than Caucasian men
• Age: PSA normally increases with age
  • The mature prostate is between 20-25 g and remains relatively constant until ≈age 50, when the gland enlarges in many men; the average prostate volume in a 60-70 year old is ≈48 g

PSA velocity[edit | edit source]

• Short-term fluctuations in PSA can occur between measurements in the presence or absence of prostate cancer, primarily as a result of physiologic variation. However, the rate of change in PSA (PSAV)—PSA corrected for the elapsed time between measurements is associated with the risk for prostate cancer
• PSAV > 0.75 ng/mL/year has been shown to be a specific marker for the presence of prostate cancer in men with PSA levels between 4-10 ng/mL
• There are conflicting studies on whether PSAV provides more information than total PSA in predicting disease aggressiveness

Free-PSA (fPSA)[edit | edit source]

• %fPSA varies directly with age and volume, and indirectly with total PSA. Does not vary by race.
• Low %fPSA is associated with increased risk of prostate cancer
  • PSA produced by malignant cells escapes proteolytic processing more frequently, resulting in a greater fraction of serum PSA complexed to α1-antichymotrypson and a lower %fPSA compared to men without cancer
  • Catalona et al. (1998)
    • Population:
      • Prospective cohort study of 773 men aged 50-75 enrolled primarily through screening centers with PSA 4-10 and palpably benign gland that underwent diagnostic biopsy
        • 49% had cancer, 51% had benign disease
    • Primary outcome:
      • %fPSA that maintained 95% sensitivity for PC detection
    • Results:
      • %fPSA was inversely associated with risk of cancer
      • AUC 0.72 %fPSA vs. 0.53 total PSA
      • %fPSA cut-off:
        • ≤25: sensitivity: 95%, specificity 20%
        • ≤22: sensitivity 90%, specificity 29%
      • INSERT FIGURE
    • Catalona, William J., et al. "Use of the percentage of free prostate-specific antigen to enhance differentiation of prostate cancer from benign prostatic disease: a prospective multicenter clinical trial." Jama 279.19 (1998): 1542-1547.
  • %fPSA as a test is FDA-approved in men with a total PSA 4-10ng/mL and negative DRE
    • %fPSA is most useful in the setting of PSA levels < 10ng/ml because the PPV of tPSA > 10- 20ng/ml has been shown to be ≈80%; it’s utility in PSA <4.0ng/ml is unknown
    • No %fPSA threshold has been established, proposed cut points generally range from 15-25%
    • Debate remains surrounding the utility of %fPSA as a prognostic biomarker
• Complexed-PSA (as opposed to the free-PSA)
  • Overall, at a high sensitivity, cPSA provides higher specificity than tPSA and comparable specificity to %fPSA in prostate cancer detection. A potential advantage of cPSA is the requirement for one assay
• 5ARIs lower total PSA levels by ≈50% after 12 months of treatment
  • With the use of 5ARIs, fPSA decreases in a similar fashion to tPSA, and the %fPSA is not altered significantly
  • Finasteride 1 mg (Propecia) used for male pattern hair loss (androgenic alopecia) results in the same decline in serum PSA levels as the 5-mg dosage used for the treatment of BPH
  • In the PCPT trial, PSA had statistically significantly better sensitivity and AUC for detecting prostate cancer in the finasteride arm[23]

Other prostate cancer biomarkers[edit | edit source]

• See Prostate Cancer: Blood, Urine and Tissue-based markers

Imaging[edit | edit source]

Primary[edit | edit source]

Transrectal ultrasound (TRUS)[edit | edit source]

• Compared to DRE, TRUS does not improve the ability to stage prostate cancer
• In general, TRUS under-stages rather than over-stages prostate cancer
• Limited detection of transition zone lesions

Magnetic Resonance Imaging (MRI)[edit | edit source]

• See Video on Approach and Principles to Prostate MRI
• MRI uses strong magnetic fields and the electromagnetic properties of hydrogen protons to generate the signal that is used to create images[24]
  • Signal intensities vary based on the hydrogen content of the tissue
  • For details, see Pooley, Robert A. "Fundamental physics of MR imaging." Radiographics 25.4 (2005): 1087-1099.

Imaging sequences[edit | edit source]