CC BY 4.0 · Indian J Med Paediatr Oncol 2023; 44(01): 130-137
DOI: 10.1055/s-0042-1759517
Review Article

Imaging Recommendations for Diagnosis, Staging, and Management of Prostate Cancer

Nilesh P. Sable
1   Department of Radiodiagnosis, Tata Memorial Hospital, Parel, Mumbai, Maharashtra, India
,
Ganesh K. Bakshi
2   Department of Urosurgery, P.D. Hinduja Hospital and Research Centre, Mumbai, Maharashtra, India
,
N. Raghavan
3   Department of Surgical Oncology, Apollo Hospitals, Chennai, Tamil Nadu, India
,
Hemang Bakshi
4   Department of Surgical Oncology, Cancer Centre, Ahmedabad, Gujarat, India
,
Rakesh Sharma
5   Department of Surgical Oncology, INDO American Basavatarakam Cancer Centre, Hyderabad, Telangana, India
,
6   Department of Pathology, Tata Memorial Hospital, Parel, Mumbai, Maharashtra, India
,
Prabhash Kumar
7   Department of Medical Oncology, Tata Memorial Hospital, Parel, Mumbai, Maharashtra, India
,
Aparna Katdare
1   Department of Radiodiagnosis, Tata Memorial Hospital, Parel, Mumbai, Maharashtra, India
,
Palak Popat
1   Department of Radiodiagnosis, Tata Memorial Hospital, Parel, Mumbai, Maharashtra, India
› Institutsangaben
 

Abstract

The Prostate Carcinoma Guidelines Panel have formulated these guidelines to assist medical professionals in the evidence-based management of prostate cancer. These have been formulated by a panel consisting of Indian multidisciplinary group of radiologists, uro-oncologists, urologists, radiation oncologists, medical oncologists, and pathologists. These recommendations present the best evidence available to the clinicians; however, using these recommendations will not always result in the best outcome. They aid in decision making for individual patients; however, these will never replace clinical expertise when making treatment decisions. Taking personal values and preferences or individual circumstances of patients into account is necessary for final treatment decision. Guidelines are not mandatory and should not to be referred as a legal standard of care.


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Introduction

The Prostate Carcinoma Guidelines Panel have formulated these guidelines to assist medical professionals in the evidence-based management of prostate cancer [PCa].

These guidelines present the best evidence available to the clinicians; however, using guideline these recommendations will not always result in the best outcome. They aid in decision making for individual patients; however, these will never replace clinical expertise when making treatment decisions. Taking personal values and preferences or individual circumstances of patients into account is necessary for final treatment decision. Guidelines are not mandatory and should not to be referred as a legal standard of care.

The Guidelines Panel consists of an Indian multidisciplinary group of radiologists, uro-oncologists, urologists, radiation oncologists, medical oncologists, and pathologists.


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Risk Factors and Etiopathogenesis

PCa remains the second most common cancer in men and the fifth leading cause of death around the globe.[1] It may be asymptomatic at the early stages and can be very slow growing which may need only active surveillance. According to the GLOBOCAN 2020 data,[1] 1,414,259 new cases of prostate cancer were reported worldwide in 2020, causing 3,75,304 deaths, with higher prevalence in developed countries.

Family history and racial/ethnic background are associated with an increase incidence PCa.

Across the globe, incidence and mortality of PCa correlate with advanced age. The mean age at the time of diagnosis approximately is 66 years in most studies. In African-American men, the incidence rates are higher than in White men, and their mortality is approximately twice as that in White men.[2]

Elevated plasma levels of prostate-specific antigen (PSA more than 4 ng/mL), a glycoprotein normally expressed by prostate tissue forms the basis of the diagnosis in most patients. However, as elevated PSA levels can also be found in men without PCa, a tissue diagnosis by biopsy remains the current standard of care to confirm cancer.

Uncertainty still exists about the relation of diet, obesity, and use of some vitamins or minerals as the cause of prostate cancer.


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Epidemiology and Clinical Presentation

Significant variation is seen in the incidence of prostate cancer across the regions and populations around the globe.[1] In 2020, 1,414,259 new cases of prostate cancer were registered worldwide, representing 7.3% of all cancers in men.[3] The age-standardized rate (ASR) was the highest in Oceania (443.5 per 100,000 people) and North America (397.9) followed by Europe (328.5). As compared to these developed countries, the Asian and African countries have low incidence (185.2 and 126.8, respectively) with incidence in India up to 95.7, the lowest incidence in Niger being 66.9.

Diet modifications and physical activity are important in prostate cancer development and progression. These are mainly related to the observed worldwide and ethnic differences in the incidence rates of prostate cancer.[4] [5] [6]

Prostate cancer incidence increases with age.[1] Though only 1 in 350 men under the age of 50 years will be diagnosed with prostate cancer,[7] the incidence rate increases up to 1 in every 52 men for ages 50 to 59 years. The incidence rate reaches 60% in men over the age of 65 years.[8]

Clinical presentation: At the early stage, many patients may be asymptomatic, often with an indolent course, who need minimal or even no treatment. In symptomatic patients, the presenting symptoms are difficulty with micturition, increased frequency, and nocturia, mimicking benign prostatic hypertrophy. PCa can also present with hematuria, hematospermia, or erectile dysfunction. In advanced stages, patients may present with severe urinary symptoms such as urinary retention and with weakness, back pain, and weight loss. Bony metastases is commonly present in metastatic disease.


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Clinical/Diagnostic Work-Up

Digital rectal examination (DRE): PCas are most commonly located in the peripheral zone and easily detected if the tumor volume is more than 0.2 mL. Abnormal DRE remains the first indicator for the PCa (approximately 18% of cases being detected by DRE alone[9] and is an indication of biopsy).

Prostate-specific antigen (PSA): PSA is a serum marker specific to the prostate; however, it is not specific to PCa. Hence, it can be seen elevated in other non-malignant conditions such as benign prostatic hypertrophy (BPH) and prostatitis. PSA seems a better predictor of cancer than either DRE or transrectal ultrasonography (TRUS) as an independent variable. Yet there are no standards defined for measuring PSA.[10] It is a continuous parameter, with higher levels indicating greater likelihood of PCa. However, PCa can also be seen with PSA levels below 4 ng/mL.

In addition to these variables, PSA density (the level of serum PSA divided by the prostate volume) or PSA doubling time and free/total PSA ratio can be also assessed for evaluation of the disease, in clinical settings.

Risk Stratification

Risk stratification is an integral part of PCa treatment and should be performed before starting management.

Patients are stratified in low-risk, intermediate-risk, and high-risk depending on PSA values, T stage of the disease and Gleason score.[11]

Low-risk

Gleason score ≤ 6, PSA ≤ 10 and stage T1-T2a

Intermediate-risk

Gleason score 7, PSA > 10–20 and stage T2b

High-risk

Gleason score 8 to 10, PSA > 20 and stage T2c


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Diagnostic Evaluation

Screening and Early Detection

Screening

Systematic examination of asymptomatic men (at risk) performed by health authorities is called screening, which is aimed at the reduction of mortality as well as maintaining the quality of life in PCa patients. Aggressive screening in USA showed decreased in mortality in PCa patients.[12]

The updated Cochrane review endorsed the following points[13]: Screening is associated with an increased diagnosis of PCa, detection of more localized disease and less detection of the advanced disease. However, no cancer specific survival benefit and overall survival benefit was seen because of screening.

Where screening is considered, a single PSA test is not enough according to the results of a randomized trial of PSA testing “CAP trial”[14]. In this trial, they concluded that single PSA screening intervention detected more number of low-risk PCa cases but had no significant effect on PCa mortality after a median follow-up of 10 years.


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Recommendations for screening

Recommendation

Level of Evidence

Strength of recommendation

1.1

Do not subject men to screening with PSA without counseling them on the potential risks and benefits.

3

Strong

1.2

Offer an individualized risk-adapted strategy for early detection to a well-informed man and a life-expectancy of at least 10 to 15 years.

3

Weak

1.3

Offer early PSA testing to well-informed men at elevated risk of having PCa in men > 50 years of age, men > 45 years of age, and a family history of PCa, men of African descent > 45 years of age, men carrying BRCA2 mutations > 40 years of age.

2a

Strong

1.4

Offer a risk-adapted strategy (based on initial PSA level), with follow-up intervals of 2 years for those initially at risk in men with a PSA level of > 1 ng/mL at 40 years of age, men with a PSA level of > 2 ng/mL at 60 years of age, Postpone follow-up to 8 years in those not at risk.

3

Weak

1.5

Stop early diagnosis of PCa based on life expectancy and performance status and in men who have a life-expectancy of < 15 years are unlikely to benefit.

3

Strong

Ultrasonography and Biopsy

The transabdominal USG has no defined role in detection of PCa, which cannot characterize the prostatic lesions adequately. Transrectal USG is also not accurate in prediction of an organ-confined disease as compared to DRE. It is commonly used in guidance of prostate biopsies. Alternatively, transperineal route can also be used for biopsy. PCa detection rates are almost similar using both the routes; however, according to a few studies, transperineal route requires more extensive local anesthesia and is associated with decreased infection rates.[15] Reliability of gray-scale TRUS for detection of PCa is very low;[16] however, recent innovations in sonography techniques such as color Doppler, elastography, and contrast-enhanced USG either alone or in various combinations can give satisfactory results in PCa diagnosis. The diagnostic yield of additional biopsies performed on hypoechoic lesions is not significant.[17]

The requirement of prostate biopsy depends on the findings of PSA levels, abnormal DRE or imaging (transrectal USG/MRI). Age of patient, various comorbidities, and therapeutic implications should also be noted and discussed with the patient before the procedure to reduce unnecessary biopsies.[18] [19]


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Multiparametric Magnetic Resonance imaging

Multiparametric magnetic resonance imaging (mpMRI) has good sensitivity for the detection and localization of ISUP grade > 2 cancers.[20] Recent Cochrane meta-analysis that compared mpMRI to template biopsies, mpMRI had a pooled sensitivity and specificity of 0.91 and 0.37, respectively, for ISUP grade > 2 cancers.[21] Similarly, for ISUP grade > 3 cancers, mpMRI pooled sensitivity and specificity were 0.95 and 0.35, respectively. In contrast, mpMRI is less sensitive in identifying ISUP grade 1 cancer. Targeting biopsies with prior mpMRI increases the detection rates of PCa with higher ISUP grades as compared to standard systematic biopsies in both the biopsy naïve patients and repeat biopsy patients. Many centers now use a combined approach of standard systematic biopsy along with mpMRI directed biopsy (MRTBx).

Repeat biopsy after previously negative biopsy:

Indications for repeat biopsy:

  • ➢ Increasing and/or persistently elevated PSA.

  • ➢ Suspicious DRE, 5–30% PCa risk.

  • ➢ Atypical small acinar proliferation (such as atypical glands suspicious for cancer), 31–40% PCa risk on repeat biopsy[22] [23];

  • ➢ Extensive (multiple biopsy sites > 3) high-grade prostatic intraepithelial neoplasia (HGPIN), approximately 30% PCa risk[23] [24];

  • ➢ A few atypical glands immediately adjacent to high-grade prostatic intraepithelial neoplasia (PINATYP), approximately 50% PCa risk[25];

  • ➢ Intraductal carcinoma as a solitary finding, > 90% risk of associated high-volume and high grade PCa[26];

  • ➢ Positive mpMRI findings.

mpMRI Protocol:

We are currently using following protocol on 1.5 T Philips MRI machine.

Sr. No.

Name of sequence

FOV (Filed of view) in mm

Slice Thickness and interslice interval (in mm)

Matrix

1

Sagittal T2W (small FOV)

200

3/0

284 × 220

2

Oblique axial T2W (small FOV)

180

3/0.3

256 × 190

3

Oblique coronal T2W (small FOV)

180

3/0.3

256 × 190

4

Axial T1W (large FOV)

363

5/1.5

406 × 296

5

Axial T2W (large FOV)

363

5/1.5

406 × 296

6

Diffusion-weighted sequence (DWI) at 0, 500, and 800

364

5/1.5

127 × 125

7

Zoom DWI at 0, 800, and 1500

180

3/0.3

64 × 62

8

Dynamic postcontrast T1W sequence (8 phases) *(small FOV)

180

4/2

64 × 64

9

Axial postcontrast fat sat T1W (large FOV)

364

5/1.5

376 × 300

10

Oblique axial postcontrast fat sat T1W (small FOV)

3/0.3

200 × 156

11

Sagittal postcontrast fat sat T1W (small FOV)

3/0.0

208 × 150

12

Coronal postcontrast fat sat T1W (small FOV)

3/0.5

208 × 152

* Dynamic T1W postcontrast sequence starts at 10 seconds from contrast injection after a mask phase, each phase is obtained 15 seconds apart.


CT SCAN

Role of CT scan in imaging of PCa is limited to nodal and metastatic staging. Although it is not advocated in detection or primary staging of PCa, a few studies show that it has some role in detection of PCas.[27]


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PET CT SCAN

PET CT scan has emerged as an important staging modality for primary as well as recurrent prostate cancer. Previously, NaF was used a radiotracer that showed a high sensitivity but low specificity. Recently, tracers such as choline, fluciclovine, and especially PSMA have shown increased detection for smaller metastatic lesions that are not easily seen on CT or MR imaging.[28] Clinical implications of these occult PET/CT detected disease may be beneficial to patients. Efforts are now targeted to define their natural history and response to treatment and an overall impact of metastasis-directed therapy detected by these investigations. In comparison, with the conventional staging approach, additional lymph nodal metastases and skeletal/visceral metastases were detected in 25% and 6% of patients, respectively.[29] Thus, PSMA PET/CT is cost-effective and can be considered as a standard modality compared to conventional imaging for initial staging of men with high-risk prostate cancer.[30]


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PET MRI

After promising results from the PSMA PET CT, researchers have now added MRI to PET component that provides highly accurate morphological information to the functional information of PET. The first two PSMA agents for PET imaging were 18F-DCFBC and 68Ga-PSMA-11. Two other agents with theranostic capabilities, the chelator-based PSMA-617 and the PSMA inhibitor for imaging and therapy PSMA-I&T are also now used. Some second-generation 18F-labeled PSMA legends were also introduced to overcome the high blood-pool activity and low tumor-to-background ratios of 18F-DCFBC, viz.,18F-DCFPyL, and 18F-PSMA-1007 (most recent), which has very low urine clearance. The MRI component has high soft tissue resolution, hence can be used for accurate delineation of the lesion (local staging, i.e., T staging). In contrast, the PSMA PET component has a higher value in detection of the metastatic lymph nodes and other metastatic lesions (can be used in N staging and M staging). Thus, PSMA PET-MRI overcomes the shortcomings of each modality when used singly. Because of these reasons, it has got higher sensitivity (up to 76%) as compared to mpMRI and PET, when these modalities are used alone.[31]


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Recommendations for PCa detections

Recommendations for all patients

Recommendation

Level of evidence

Strength of recommendation

2.1.1

Systematic biopsy is an acceptable approach in case mpMRI is not available.

3

Strong

Do not use multiparametric magnetic resonance imaging (mpMRI) as an initial screening tool.

3

Strong

2.1.3.

Adhere to PI-RADS guidelines for mpMRI acquisition and interpretation and evaluate mpMRI results in multidisciplinary meetings with pathological feedback.

3

Strong

Recommendations in biopsy naïve patients

2.2.1

2.2.1. Perform mpMRI before prostate biopsy.

1a

Strong

2.2.2

2.2.2. When mpMRI is positive (PI-RADS > 3), combine targeted and systematic biopsy.

2a

Strong

2.2.3

2.2.3. When mpMRI is negative (PI-RADS < 2), and clinical suspicion of prostate cancer is low, omit biopsy based on shared decision making with the patient.

2a

Weak

Recommendations in patients with prior negative biopsy:

2.3.1

Perform mpMRI before prostate biopsy.

1a

Strong

2.3.2

When mpMRI is positive (i.e., PI-RADS > 3), perform targeted biopsy only.

2a

Weak

2.3.3

When mpMRI is negative (i.e., PI-RADS < 2), and clinical suspicion of prostate cancer is high, perform systematic biopsy based on shared decision making with the patient.

2a

Strong

Staging: The extent of PCa is evaluated by DRE and PSA, along with mpMRI, bone scanning and CT scan.

Stage: Can be clinical (cT) or pathological (pT)T staging as per the AJCC 8th cancer staging edition.[32] Complete clinical and pathological T staging is given in [Table 1] in detail:

Table 1

T Staging (Clinical and Pathological)

Clinical T staging(cT):

Tx

Primary tumour cannot be assessed

No evidence of primary tumour

T1

A clinically inapparent tumour that is not palpable

T1a

Tumour incidental histologic finding in 5% or less of tissue resected

T1b

Tumour incidental histologic finding in more than 5% of tissue resected

T1c

Tumour identified by needle biopsy found in one or both sides, but not palpable

T2

Tumour is palpable and confined within the prostate

T2a

Tumour involves one-half of one side or less

T2b

Tumour involves more than one-half of one side but not both sides

T2c

Tumour involves both sides

T3

Extraprostatic tumour that is not fixed or does not invade adjacent structures

T3a

Extraprostatic extension (unilateral or bilateral)

T3b

Tumour invades seminal vesicle(s)

T4

Tumour is fixed or invades adjacent structures other than seminal vesicles such as external sphincter, rectum, bladder, levator muscles, and/or pelvic wall

Pathological T staging(pT):

T2

Organ confined.

T3

Extraprostatic extension.

T3a

Extraprostatic extension (unilateral or bilateral) or microscopic invasion of the bladder neck

T3b

Tumour invades seminal vesicle(s)

T4

T4: Tumour is fixed or invades adjacent structures other than seminal vesicles such as external sphincter, rectum, bladder, levator muscles, and/or pelvic wall

For T staging, only DRE findings are taken into account as of now. TRUS has no value in prediction of an organ-confined disease. Though mpMRI has good specificity for detection of T3 tumors, it is still not recommended for staging of the disease, in view of low sensitivity.[33] However, it can be used for planning of disease treatment.

N Stage: The regional nodes are assessed in N staging, which are defined as the nodes confined to the true pelvis (pelvic nodes below the bifurcation of the common iliac arteries). Detailed N staging in [Table 2].

Table 2

N Staging

Nx

Regional nodes were not assessed.

N0

No positive regional nodes.

N1

Metastases in regional node(s).

Note: A node along the common iliac arteries would be considered as M1a.


Abdominopelvic CT scan and MRI have been tried for nodal staging in PCa patients, which consider the size of the nodes to label them malignant (short axis more than 8 mm in the pelvic cavity and more than 10 mm outside the pelvic cavity). However, these techniques have very low sensitivity.[34] Choline PET CT also has low sensitivity.[35] According to a few studies, PSMA PET/CT has higher sensitivity for LN metastases as compared to mpMRI, abdominal contrast-enhanced CT or choline PET/CT.[36]

Various imaging modalities are used for M staging including 99mTc-Bone labelled bone scan, Fluoride PET and PET/CT, choline PET/CT, whole body MRI and PSMA PET CT, amongst these PSMA PET CT outperforms the other modalities with sensitivity (33-99%) and specificity (> 90 %).[37] Detailed M staging is shown in [Table 3].

Table 3

M Staging

M0

No distant metastasis.

M1

Distant metastasis

M1a

Metastasis to non-regional lymph node(s).

M1b

Metastasis to Bone(s).

M1c

Other site(s) with or without bone disease e.g., lungs, liver, brain

Guidelines for staging of prostate cancer:

Recommendation

Level of evidence

Strength of recommendation

3.1

Any risk group staging: use pre-biopsy mpMRI for local staging information.

2a

Strong

3.2

Low-risk localized disease. Do not use additional imaging for staging purposes.

2a

Strong

3.3

Intermediate-risk disease. In ISUP grade > 3, include at least cross-sectional abdominopelvic imaging and a bone-scan for metastatic screening.

2a

Weak

3.4

High-risk localized disease/locally advanced disease. Perform metastatic screening including at least cross-sectional abdominopelvic imaging and a bone-scan.

2a

Strong

Follow Up: Imaging techniques are not recommended in routine follow-up of localized PCa as long as the PSA is not rising. Imaging is only suggested in patients for whom the findings will affect treatment decisions, either in case of biochemical recurrence or in symptomatic patients. PSMA PET CT is better than the other modalities such as TRUS, CT scan, MRI, or choline PET CT as imaging of choice in such patients.[38]

To conclude, we can follow the flow chart for staging, diagnosis, and management of PCa


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Conflict of Interest

None declared.


Address for correspondence

Nilesh P. Sable, MD
Department of Radiodiagnosis, Tata Memorial Hospital
Parel, Mumbai, Maharashtra
India   

Publikationsverlauf

Artikel online veröffentlicht:
06. März 2023

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