ABSTRACT
Objective:
This study aimed to investigate the correlation between index lesion prostate imaging-reporting and data system (PI-RADS) version-2 score and histopathological outcomes of prostatectomy specimens.
Materials and Methods:
A total of 78 male patients with prostate cancer (PCa) treated with robot-assisted radical prostatectomy between August 2015 and June 2020 were included in this study. In this cohort, suspicious lesions on multiparametric magnetic resonance imaging (mpMRI) were scored according to PI-RADS version-2 criteria. MpMRI-targeted prostate biopsy was performed for all suspicious lesions with a PI-RADS score of ≥3 followed by systematic prostate biopsy. The relationship between index lesion PI-RADS score and histopathological outcomes of prostatectomy specimens were evaluated statistically.
Results:
The mean age of the patients was 65.0±7.0 years. The distribution of PI-RADS scores of 3, 4, and 5 of the index lesions were 6 (7.7%), 29 (37.2%), and 43 (55.1%), respectively. Lower tumor volume and tumor volume ratio were observed in patients with a PI-RADS score of 3 when they were compared with patients with PI-RADS scores of 4 and PI-RADS-5 (p<0.001, for each). No significant correlation was found between index lesion PI-RADS score in mpMRI and clinically significant PCa in prostatectomy specimens (r<0.200, p>0.05). However, a significant correlation was observed between index lesion PI-RADS score and extracapsular extension (ECE), as well as seminal vesicle invasion (SVI) and pT stage (r=0.327, p=0.004; r=0.276, p=0.014, r=0.348, p=0.002, respectively).
Conclusion:
Increased index lesion PI-RADS scores were associated with ECE, SVI, higher tumor volume, tumor volume ratio, and pT stages. Increased index lesion PI-RADS score in mpMRI may be helpful in prediction of locally advanced PCa in prostatectomy specimens.
Introduction
Prostate cancer (PCa) is the second most common cancer in men worldwide with an estimated 1,276,106 new cases and 358,989 deaths (1). Transrectal ultrasound-guided systematic prostate biopsy (SBx) with a minimum of 10-12 cores has been accepted as the standard diagnostic approach for the evaluation of patients who have a clinical suspicion for PCa (2). Recently, multiparametric prostate magnetic resonance imaging (mpMRI), which provides a better depiction of prostate anatomy as well as functional imaging, has been recommended for the evaluation of any patient who has a suspicion of PCa with or without a history of prior biopsy (2,3,4).
The European Society of Urogenital Radiology introduced the prostate imaging-reporting and data system (PI-RADS) version-1 (v1) for standardization of interpretation and reporting of mpMRI in 2012 (5). A Likert-type scoring system is used in PI-RADS to demonstrate the likelihood of the presence of clinically significant (cs) PCa. Several limitations such as suboptimal definition of the exact scoring with relatively higher subjectivity in the evaluation of suspicious lesions in PI-RADSv1 system restricted its use (6). Subsequently, PI-RADS version-2 (v2) was introduced in 2015 and several studies suggested that PI-RADSv2 is more suitable for routine clinical use due to its higher reproducibility and better inter-observer agreement for malignant lesions when compared to PI-RADSv1 (6,7,8).
Although higher detection rates of csPCa in mpMRI-targeted prostate biopsy (TBx) specimens in patients with increased PI-RADS scores have been reported in many studies, currently, the exact relationship between PI-RADS scores and pathological outcomes at the final prostatectomy specimens remains unclear (3,9,10,11,12,13,14). Several retrospective studies have investigated this topic with controversial outcomes (15,16,17). In this context, the present study aimed to evaluate the association of PI-RADS scores in mpMRI with the pathological outcomes of prostatectomy specimens.
Materials and Methods
Study Population
We retrospectively reviewed medical records of 329 male patients who underwent transperineal prostate needle biopsy in Acıbadem Mehmet Ali Aydinlar University, Altunizade and Kadıköy Hospitals, Clinic of Urology, between August 2015 and June 2020. Patients who underwent transperineal TBx, with concomitant 12-core SBx, diagnosed with PCa and treated with robot-assisted radical prostatectomy were included in the study. The study was approved by the local Institutional Ethics Committee (IRB No:2021-15/01).
All steps of the study were planned and conducted in accordance with the principles of the Declaration of Helsinki. A written informed consent on admittance to hospital was obtained from all individuals, which permitted the use of respective medical information in clinical studies.
Demographic characteristics, preoperative clinical characteristics, pathological findings of each biopsy type, and prostatectomy specimens were noted in detail for each patient. Patients who had benign tissue in biopsy pathology, underwent SBx only, had metastatic PCa at clinical staging, did not accept surgery or treated with radiotherapy and had missing clinical data were excluded. Finally, a total of 78 male patients who met the selection criteria were included in this study. The PI-RADS score groups (scores of 3, 4, and 5) were compared statistically.
mpMRI and Determination of Suspicious Lesions
All patients were evaluated with 3-T mpMRI (Magnetom Skyra, Siemens Healthineers, Erlangen, Germany) before the prostate biopsy. All mpMRI studies were evaluated by the same dedicated radiologist (A.D.), and all PI-RADSv2 lesions ≥3 were mapped. The border of the prostate and lesions were outlined and saved as a biopsy plan by MIM Symphony Dx™ Software Inc. version 6.7 (Cleveland, OH, USA). The lesion with the highest PI-RADSv2 score was determined as the index lesion in case of multiple suspicious lesions in mpMRI. If more than one lesion had the same highest PI-RADSv2 score, the lesion with the largest volume calculated by MIM Symphony Dx™ software was accepted as the index lesion.
Transperineal mpMRI-targeted and Systematic Prostate Biopsy
All transperineal TBx and SBx procedures were performed under sedoanalgesia in a dorsal lithotomy position. An 18-gauge automatic biopsy gun with a 19-mm sample notch was used in biopsy procedures (Tru-Core™ II URO Automatic Biopsy Instrument, Argon Medical Devices, Inc., TX, USA). A single-dose parenteral antibiotic as prophylaxis was administered to all patients during anesthesia induction (ceftriaxone sodium 1 g or cefuroxime sodium 1.5 g, intravenous). Moreover, 2-4 samples were taken from each of the suspicious lesions with PI-RADS score of ≥3 using a stepper and template grid as previously reported (18). Additional biopsies were performed if necessary (e.g., for the hypoechoic lesions on ultrasonography). All biopsy samples and whole-mount sections after radical prostatectomy were evaluated by a dedicated uropathologist (H.D.) in accordance with the 2014 International Society of Urologic Pathology (ISUP) criteria (19). csPCa in prostatectomy specimens was defined as the presence of Gleason score (GS) >6 or GS 6 disease with tumor volume greater than 0.5 cm3 (20).
Statistical Analysis
Statistical analysis was performed using the Statistical Package for the Social Sciences version 22.0 software (IBM Corp., Armonk, NY, USA). Shapiro-Wilk test was used to check the normality of data for quantitative variables. Descriptive data were expressed in mean ± standard deviation and median (interquartile range), or number and frequency. Fisher’s exact and Kruskal-Wallis tests were used to determine homogeneity, independence, and differences between related groups as indicated. The post-hoc analysis was conducted by Tamhane’s test. The correlation coefficient and significance for the relationships between the index lesion PI-RADS scores and various variables in biopsy and prostatectomy specimens were calculated with Spearman’s test. A two-sided p-value of <0.05 was considered statistically significant.
Results
The mean age of the patients was 65.0±7.0 years, and the median PSA and PSA density were 5.52 (4.20-8.80) ng/mL and 0.13 (0.09-0.17) ng/mL2, respectively (Table 1). Preoperative demographic and clinical characteristics of the participants and prostatectomy pathology results are summarized in Table 1.
The distribution of PI-RADS scores of 3, 4, and 5 of the index lesions were 6 (7.7%), 29 (37.2%), and 43 (55.1%), respectively. The median number of suspicious lesion detected in mpMRI was 3 (2-4), and the median number of tumor-positive lesion was 1 (1-2) in TBx. The median number of cores sampled and tumor-positive cores in SBx were 12 (12-12) and 3 (1-5), respectively. PCa was detected in 66 (84.6%) patients by TBx and 68 (87.2%) patients by SBx. csPCa was detected by TBx and SBx in 57 (73.1%) and 61 (78.2%) patients, respectively.
Increased PSA levels was observed in patients with higher PI-RADS score; however, no significant difference was found between the PSA levels of the patients when they were compared according to index lesion PI-RADS score (p>0.05) (Table 2). A significant difference was noted among the PI-RADS score groups in terms of the median number of tumor positive lesions in TBx (p=0.041) (Table 2). In the post-hoc analysis, significant difference was found between PI-RADS-3 and PI-RADS-5 groups in terms of the number of tumor positive lesions in TBx (p=0.047). In the post-hoc analysis, lower tumor volume and tumor volume ratio were observed in PI-RADS-3 when compared with PI-RADS-4 and PI-RADS-5 groups (p<0.001, for each). Higher pT stages were observed with increased PI-RADS score, pT3b disease was only seen in the PI-RADS-5 group, while none of the patients in the PI-RADS-3 group had ≥pT3a disease (Table 2).
No significant correlation was found between index lesion PI-RADS score and PSA and PSA density (r=0.121, p=0.293; r=0.120, p=0.296, respectively). Moreover, no significant correlation was noted between index lesion PI-RADS score and number of tumor positive lesions in TBx (r=0.151, p=0.188). Significant linear correlation was observed between index lesion PI-RADS score and csPCa in TBx and SBx (r=0.300, p=0.008; r=0.249, p=0.030, respectively) (Table 3). Similarly, a significant correlation was observed between index lesion PI-RADS score and extracapsular extension (ECE), as well as seminal vesicle invasion (SVI) and pT stage (r=0.327, p=0.004; r=0.276, p=0.014, r=0.348, p=0.002, respectively). Correlation analysis between the index lesion PI-RADS score and prostate biopsy and prostatectomy pathology are summarized in Table 3.
Discussion
This study aimed to assess the relationship between index lesion PI-RADS score in mpMRI and various pathological features of prostatectomy specimens in patients who underwent transperineal TBx and/or SBx and subsequently treated with robot-assisted radical prostatectomy. Based on our study results, increased index lesion PI-RADS scores were associated with higher tumor volume, tumor volume ratio, and pT stages in prostatectomy specimens. Moreover, the frequency of csPCa in prostatectomy specimens increased in patients who had a higher index lesion PI-RADS score. However, no significant difference was found between the PI-RADS score groups in terms of csPCa, and no correlation was noted between the index lesion PI-RADS score and csPCa in prostatectomy specimens. The lack of significant correlation noted between the index lesion PI-RADS score and csPCa in prostatectomy specimens is most likely caused by the very high ratio of csPCa in this cohort. As we presented above, nearly all patients (96.2%) had csPCa in prostatectomy specimens. By contrast, we observed significant correlation between the index lesion PI-RADS scores and csPCa in both TBx and SBx. Therefore, indirect evidence may suggest that increased index lesion PI-RADS scores may also play a role in predicting csPCa in prostatectomy specimens. Furthermore, higher index lesion PI-RADS scores were correlated with ECE and SVI in prostatectomy specimens as well as higher volume tumors with higher ISUP-grade group category. In this context, our data may suggest that increased index lesion PI-RADS score in mpMRI may predict locally advanced PCa in prostatectomy specimens.
Currently, mpMRI has been widely accepted as a standard imaging modality in the diagnostic pathway and treatment decision process of PCa with its claimed higher sensitivity for the detection of csPCa (9,21). Previously reported detection rates of csPCa for PI-RADS lesions with a score of 3, 4, and 5 ranges from 0% to 66%, 21% to 98%, and 75% to 99%, respectively (9,10,11). Our observation for csPCa ratios for index lesions with PI-RADS scores of 4 and 5 in prostatectomy specimens were similar; however, the csPCa ratio for the index lesion with a PI-RADS score of 3 was relatively higher in our study than in other studies. The higher csPCa ratios for PI-RADS 3 lesions may be attributed to the inclusion of only 6 patients with a PI-RADS score of 3 in our study cohort. In addition, although more than 95% of our patients had csPCa, these patients with an allocated PI-RADS score of 3 may represent biologically aggressive tumors with deceiving radiological characteristics. An observer bias is also a possibility.
The role of PI-RADS scoring in evaluation of tumor characteristics for clinical decision-making has been a topic of interest more recently. Several studies have reported the effect of PI-RADS vs. scoring on selecting possible candidates for active surveillance (AS) (22,23,24). Woo et al. (23) reported that PI-RADSv2 and PSA density were independent predictors of pathological downgrading in prostatectomy specimens in patients who had GS 7 (3+4) PCa in the prostate biopsy. In this study, the authors concluded that mpMRI might help identify patients who had an overestimated GS in SBx and assist in selecting potential candidates for AS (23). Similarly, a study reported that combination of PSA density (for threshold ≥0.15 ng/mL2) and PI-RADS score could help minimize the number of missed csPCa in men with a PI-RADS score of ≤3 (25). In another interesting study, PI-RADSv2 score of >3 and front-to-total ratio of periprostatic fat tissue, which was measured in mpMRI and hypothesized as an influencer of the tumor microenvironment by paracrine effect, were independent risk factors for pathologic upgrading in prostatectomy specimens in patients with a biopsy GS 6 (3+3) (24). In the present study, we observed worse pathological outcomes such as higher frequency of ECE and SVI in prostatectomy specimens in patients with increased PI-RADS scores. Therefore, we also suggest that AS may not be a good treatment choice for patients with high PI-RADS (4 and 5) scores.
Slaoui et al. (15) investigated the correlation between PI-RADSv2 score in mpMRI and GS of both prostate biopsies and prostatectomy specimens. In this retrospective study, no significant concordance was found for GS in TBx and prostatectomy specimens according to the index lesion PI-RADS score (15). By contrast, similar to our study results, a retrospective study reported a significant association between PI-RADS scores and ECE and large tumor volume in a large number of patients who were eligible for AS (16). In this study, upgrading in prostatectomy specimens and unfavorable prognosis were also demonstrated, and the authors concluded that mpMRI and PI-RADS scoring could be used as a supporting parameter for a more accurate selection of patients eligible for AS (16). Similarly, adverse pathological outcomes such as tumor volume, ECE, lymphovascular invasion, and SVI were also reported in patients with increased PI-RADS scores in the most recent and well-designed multicenter study that investigated the correlation between PI-RADS and histopathological outcomes of prostatectomy specimens (17). Another recent study evaluated the correlation between PI-RADSv2 scores and several outcomes of prostatectomy specimens for central and peripheral tumors separately (26). A poor correlation between PI-RADSv2 score and final GS was reported for both central and peripheral tumors, while a moderate-to-high correlation was reported between PI-RADSv2 score and tumor volume (26). Similar to these studies, in the present study, we observed worse histopathological outcomes such as higher tumor volume, pT stage, ECE, and SVI in prostatectomy specimens in patients with increased index lesion PI-RADS scores.
Study Limitations
This study has several limitations. First, the retrospective and non-randomized nature of this study and the relatively small sample size introduce the possibility of selection bias. Second, all PI-RADS lesions in mpMRI were interpreted by only one radiologist, and all histopathological specimens were evaluated by only one pathologist. Therefore, we were unable to evaluate the inter-observer variability for outcomes. By contrast, we believe that our study results may contribute to the body of knowledge on this subject, in which no consensus has been revealed and has not been well investigated yet. Further investigations with larger cohorts, particularly including more patients with index lesion PI-RADS score of 3, are needed to validate the correlation between index lesion PI-RADS score in mpMRI and histopathological outcomes of prostatectomy specimens.
Conclusion
In this study, higher tumor volume, tumor volume ratio, and pT stages in prostatectomy specimens were observed in patients with increased index lesion PI-RADS score in mpMRI. The frequency of csPCa in prostatectomy specimens also increased in these patients. However, no significant difference was found between the PI-RADS score groups in terms of csPCa, and no correlation was observed between the index lesion PI-RADS score and csPCa in prostatectomy specimens. In addition, higher index lesion PI-RADS scores were correlated with ECE and SVI in prostatectomy specimens. In this context, increased index lesion PI-RADS scores in mpMRI may predict locally advanced PCa in prostatectomy specimens. Therefore, AS may not be a good treatment choice for patients with increased PI-RADS scores. Further well-designed prospective, randomized studies with larger cohorts are needed to confirm our study results.
Acknowledgements
Publication: The results of the study were not published in full or in part in form of abstracts.
Contribution: There is not any contributors who may not be listed as authors.
Conflict of Interest: No conflict of interest was declared by the authors.
Financial Disclosure: The authors declared that this study received no financial support.
Ethics
Ethics Committee Approval: Acıbadem Mehmet Ali Aydınlar University and Acıbadem Healthcare Institutions Medical Research Ethics Committee, IRB No:2021-15/01.
Informed Consent: A written informed consent on admittance to hospital was obtained from all individuals, which permitted the use of respective medical information in clinical studies.
Peer-review: Externally peer-reviewed.
Authorship Contributions
Supervision: A.D., H.D., L.T., Concept: B.Ö., C.A., L.T., Design: B.Ö., C.A., L.T., Data Collection or Processing: N.K., Analysis or Interpretation: N.K., M.B.Ö., Literature Search: N.K., M.B.Ö., Writing: N.K., M.B.Ö.