Journal List > Investig Clin Urol > v.60(1) > 1110441

Shoji: Magnetic resonance imaging-transrectal ultrasound fusion image-guided prostate biopsy: Current status of the cancer detection and the prospects of tailor-made medicine of the prostate cancer

Abstract

Multi-parametric magnetic resonance imaging (mpMRI) has been increasingly used to diagnose clinically significant prostate cancer (csPCa) because of its growing availability and its ability to combine anatomical and functional data. Magnetic resonance imaging (MRI)-transrectal ultrasound (TRUS) fusion imaging provides MRI information with TRUS images for prostate biopsies. This technique combines the superior sensitivity of MRI for targeting suspicious lesions with the practicality and familiarity of TRUS. MRI-TRUS fusion image-guided prostate biopsy is performed with different types of image registration (rigid vs. elastic) and needle tracking methods (electromagnetic tracking vs. mechanical position encoders vs. image-based software tracking). A systematic review and meta-analysis showed that MRI-targeted biopsy detected csPCa at a significantly higher rate than did TRUS-guided biopsy, while it detected significantly fewer cases of insignificant PCas. In addition to the high accuracy of MRI-targeted biopsy for csPCa, localization of csPCa is accurate. The ability to choose the route of biopsy (transperineal vs. transrectal) is required, depending on the patients' risk and the location and size of suspicious lesions on mpMRI. Fusion image-guided prostate biopsy has the potential to allow precise management of prostate cancer, including active surveillance, radical treatment, and focal therapy.

INTRODUCTION

Some prostate cancers (PCas) are visible on transrectal ultrasound (TRUS) and can be targeted by an experienced ultrasonographer or urologist [12], but detecting clinically significant PCa (csPCa; defined as at least one core with a Gleason score of 3+4 or 6 with a maximum cancer core length longer than 4 mm) [3] with TRUS is difficult. To improve the detection rate of csPCa, accurate needle placement into the cancerous lesion is essential. Recently, multi-parametric magnetic resonance imaging (mpMRI) has been increasingly used to diagnose csPCa because of its usefulness in detection with a combination of anatomical and functional data [45]. In the 2014 European Association of Urology guidelines, mpMRI was regarded as a particularly accurate method for detecting anterior tumors that are usually missed by systematic transrectal biopsy, and thus have the risk of a repeat (targeted) biopsy [6].
Since mpMRI has improved the detection of the csPCa in the prostate [789], several magnetic resonance imaging (MRI)-guided biopsy methods have been used, such as MRI-TRUS fusion image-guided biopsy, in-bore MRI-targeted biopsy, and cognitive biopsy. MRI-TRUS fusion imaging provides MRI information with TRUS images, which are used in prostate biopsy. This technique combines the superior visibility of MRI for targeting suspicious lesions with TRUS for real-time guidance. In-bore MRI-targeted biopsy is a direct method using MRI [1011]. A systematic review showed no significant differences in detection of PCa between MRI-TRUS fusion image-guided biopsy and in-bore MRI-targeted biopsy (p=0.13), and between MRI-TRUS fusion image-guided biopsy and cognitive biopsy (p=0.11) [12]. However, in-bore MRI-targeted biopsy is not acceptable in most hospitals because of its high expense and time constraints, and the frequent need for general anesthesia. Cognitive biopsy is a target biopsy based on the examiner's suspicions of a lesion on mpMRI without any fusion device. Cognitive biopsy has improved accuracy over conventional systematic biopsy [13141516]. Haffner et al. [13] reported that the accuracy of targeted biopsy detection was better than that of systematic biopsies for significant cancer detection (p<0.001). They also found that the maximal cancer core length was 5.56 mm for targeted biopsies and 4.70 mm for systematic biopsies (p=0.002). Similarly, Park et al. [14] reported that cancer detection was significantly higher in cognitive biopsies (29.5%) than in systematic biopsies (9.8%) (p=0.03). These authors also found a significantly higher positive percent core in cognitive biopsies than in systematic biopsies (p<0.001). In men with previous negative biopsies, the cancer detection rate of cognitive targeted biopsies (45.5%) was significantly higher than that of systematic biopsies (24.4%) (p=0.01) [15]. However, human error was reported as a disadvantage of cognitive biopsy when the target is less than 10 mm in diameter and there is the inability to track the location of each biopsy site [17]. Specialists with experience in prostate biopsy s have performed cognitive fusion biopsies with success [1314151618].
This review article focuses on the development of mpMRI for detecting csPCa and MRI-TRUS fusion image-guided prostate biopsy. We also review the prospects for tailored treatment enabled by development of accurate detection and localization of csPCa with MRI-TRUS fusion image-guided prostate biopsy.

1. Detection of csPCa with mpMRI

For detection of csPCa, mpMRI can be performed at 1.5Tesla (T) or 3.0T, using either a combination of an endorectal coil and a pelvic phased-array coil, or a pelvic phased-array coil only. The use of the endorectal coil and 3.0T imaging is optional [1920]. Currently, mpMRI includes a combination of high-resolution T2-weighted images (T2WIs), and at least two functional MRI techniques, such as diffusion-weighted images (DWIs), the apparent diffusion coefficient (ADC), or dynamic contrast-enhanced (DCE) MRI (Fig. 1) [19]. These techniques provide better characterization than T2WIs with only one functional technique [1]. Magnetic resonance spectroscopy is considered as an optional modality and has been relegated to the research setting [19]. Within mpMRI components, the relative clinical value of its component techniques differs. T2WIs provide the best depiction of the intra-prostatic structures, such as the zones, urethra, ejaculatory ducts, and capsule [1]. DCE imaging is used for evaluating tumor vascularity [21]. In a previous report, DCE was able to detect tumor vascularity in 92.9% of patients with csPCa [22]. DWI quantifies free water motion, also known as ‘Brownian’ motion [23]. An ADC map is calculated from DWI, and is able to assess the aggressiveness of PCa. The ADC corresponds to greater restriction in free water motion. This is likely achieved on the basis of increased cellular density compared with normal prostate tissue, and cancer tissue shows a lower ADC value than normal prostate tissue [23]. Furthermore, ADC values correlate with Gleason scores [242526]. However, benign prostatic hyperplasia and prostatitis show high-signal intensity on DWIs and a low ADC, which suggest cancer lesions [1]. Therefore, detection of PCa in the transition zone is regarded as challenging [27]. Previous reports have shown that localization and pathological diagnosis of the index lesion, which is the lesion with the highest Gleason score or large volume, was accurately achieved in >92% of patients [2829]. In a comparative histological study between PCa foci that were detected and missed using mpMRI, histopathological features of cancer size, Gleason score, and solid growth were significantly different between detected and missed tumors on mpMRI (p<0.0001) [30]. Independent predictors of identification of significant PCa by mpMRI were size (odds ratio [OR], 5.38; p=0.0077), Gleason score (OR, 5.12; p=0.0094), and solid growth (OR, 17.83; p<0.0001) in multivariate analysis [30].
To standardize evaluation and reporting of mpMRI findings for diagnosing PCa, the European Society of Urogenital Radiology published guidelines, termed the Prostate Imaging and Reporting and Data System (PI-RADS) [1]. PI-RADS categories range from 1 to 5, with 5 the most likely to represent csPCa [1]. In a diagnostic meta-analysis, the sensitivity and specificity were 0.78 (95% confidence interval [CI], 0.70–0.84) and 0.79 (95% CI, 0.68–0.86), respectively [31]. A previous report showed that the areas under curves (AUCs) for cancer detection with PI-RADS in the peripheral zone and transition zone were 0.97 and 0.60, respectively [32]. Based on these results, PI-RADS is regarded as a reliable method of diagnosing PCa. PI-RADS version 2 improves and standardizes communication between radiologists and urologists to detect or exclude the presence of csPCa with a high likelihood [33].

2. Diagnostic accuracy of detecting csPCa with MRI-targeted biopsy

In a systematic review, the overall PCa detection rate was not significantly different between any methods of MRI-targeted biopsy and TRUS-guided biopsy [12]. However, the detection rates of PCa per core demonstrated that MRI-targeted biopsy cores had a significantly higher yield of PCa detection compared with TRUS-guided biopsy cores (relative yield: 3.91 [95% CI, 3.17–4.83], yield of MRI-guided biopsy: 0.41 [95% CI, 0.33–0.49], yield of TRUS-guided biopsy: 0.10 [95% CI, 0.08–0.13]) [12]. In detection of csPCa, MRI-targeted biopsy detected csPCa significantly more frequently than did TRUS-guided biopsy, with a relative sensitivity of 1.16 (95% CI, 1.02–1.32; sensitivity for MRI-targeted biopsy: 0.90 [95% CI, 0.85–0.94], sensitivity for TRUS-guided biopsy: 0.79 [95% CI, 0.68–0.87]) [12]. MRI-targeted biopsy detected significantly less insignificant PCa than did TRUS-guided biopsy, with a relative yield of 0.47 (95% CI, 0.35–0.63; yield for MRI-guided biopsy: 0.07 [95% CI, 0.04–0.10], yield for TRUS-guided biopsy: 0.14 [95% CI, 0.11–0.18]) [12]. With regard to comparison of MRI-targeted biopsy, in-bore MRI-targeted biopsy had a significant advantage compared with cognitive biopsy for overall detection of PCa (p=0.02). However, there was no significant difference in detection of PCa between MRI-TRUS fusion image-guided biopsy and inbore MRI-targeted biopsy (p=0.13) [12].
In a meta-analysis of 16 reports with 1,926 patients, MRI-targeted biopsy was performed with the transrectal approach based on MRI before the biopsy [34]. Additionally, TRUS-guided biopsy was performed without information of MRI, with a range of eight to 12 cores depending on prostate volume. MRI-targeted biopsy and TRUS-guided biopsy did not differ in overall PCa detection rates (sensitivity, 0.85; 95% CI, 0.80–0.89 vs. sensitivity, 0.81; 95% CI, 0.70–0.88) [34]. However, detection of csPCa in MRI-targeted biopsy was higher than that in TRUS-guided biopsy (sensitivity, 0.91; 95% CI, 0.87–0.94 vs. sensitivity, 0.76; 95% CI, 0.64–0.84), and there was a lower rate of insignificant cancer detection (sensitivity, 0.44; 95% CI, 0.26–0.64 vs. sensitivity, 0.83; 95% CI, 0.77–0.87) [34]. Subgroup analysis showed an improvement in significant detection of csPCa by MRI-targeted biopsy in men with a previous negative biopsy than in men with an initial biopsy (relative sensitivity, 1.54; 95% CI, 1.0–2.57 vs. relative sensitivity, 1.10; 95% CI, 1.00–1.22) [34].

3. Clinical results of MRI-TRUS fusion image-guided prostate biopsy with different devices

Recently, some devices of MRI-TRUS fusion image-guided prostate biopsy have become commercially available. These devices differ by type of image registration of rigid or elastic and the needle tracking method of electromagnetic tracking or mechanical position encoders vs. image-based software tracking (Fig. 2). In image registration, rigid image registration overlays mpMRI images to TRUS images during the biopsy without adjusting for deformation of the prostate owing to the pressure of the TRUS probe [35]. However, elastic fusion adopts deformation, and therefore, it is expected to be more accurate than rigid image registration (Fig. 3) [3637]. In 2013, the BioJet (D&K Technologies GmbH, Barum, Germany) was introduced to Japan [38]. BioJet version 2.0 induces elastic registration and uses the needle tracking method with a mechanical position-encoded stepper; elastic registration matches the corresponding point landmarks and aligns them with contours of the prostate surface [39]. Using a position-encoded mechanical stepper, the three-dimensional (3D) location of the TRUS probe is calculated by direct attachment to the mechanical stepper [39]. Angle sensors in the mechanical stepper encode and automatically relay the 3D position of the probe and needle to the computer [39]. Fig. 4 shows the process of an MRI-TRUS fusion image-guided transperineal biopsy with BioJet version 2. In our experience, the detection rate of csPCa of lesions with the PI-RADS category 5 is 80% [39]. Furthermore, detection rates for biopsy-proven csPCa among targeted lesions ≤10 mm and >10 mm are similar to those with PI-RADS categories of 4 (50% vs. 51%; p=0.707) and 5 (75% vs. 68%; p=0.386) [39]. We found that receiver operating characteristic curves with PI-RADS categories showed areas under the curves (AUCs) that were significantly greater than non-discrimination for all targeted lesions (AUC, 0.835; 95% CI, 0.792–0.879; p<0.0001), lesions ≤10 mm (AUC, 0.855; 95% CI, 0.805–0.905; p<0.0001), and lesions >10 mm (AUC, 0.835; 95% CI, 0.844–0.903; p<0.0001) [39]. Our results showed the advantages of MRI-TRUS fusion image-guided prostate biopsy. A previous report showed that, with a similar device, BiopSee (Pi Medical Ltd, Athens, Greece), transperineal MRI-TRUS fusion image-targeted biopsy detected 79% of csPCas in analysis of whole-mount specimens [40]. The Artemis system (Eigen, Grass Valley, CA, USA), which uses elastic fusion and position-encoded joints in robotic arms, is used for transrectal targeted biopsy. A previous report showed that the cancer core detection rates in targeted biopsies (9.4%) were significantly higher than those in 12-core systematic biopsy cores (5.7%; p<0.05) [41]. Furthermore, the median lesion core length (3.75 mm vs. 2.86 mm; p<0.05) and the percentage of cancer core length (34.3% vs. 26.1%; p<0.05) in targeted biopsies were significantly higher than those in 12-core systematic biopsies [41]. The UroNav system (Invivo, Gainesville, FL, USA) uses elastic fusion and electromagnetic needle tracking. A previous study showed that transrectal target biopsies with the UroNav (n=461) diagnosed 30% more PCas with a Gleason score ≥4+3 than did 12-core template systematic biopsies (n=469) (173 cases vs. 122 cases; p<0.001) [42]. In another report, the cancer detection rate for transrectal targeted biopsy using the UroNav system was significantly higher (48.1%, 39/81 patients) than that for transrectal biopsy with visual registration (34.7%, 52/150 patients; p=0.04) or 12-core transrectal systematic biopsy (32.0%, 32/100 patients; p=0.03) [43]. In the Urostation system (Koelis, Meylan, France), elastic fusion and 3D TRUS image needle tracking are used [44]. A previous study showed that targeted biopsies with the Urostation had significantly higher overall cancer detection rates (31% vs. 7.5%; p<0.001) and detection rates for clinically significant cancers (43% vs. 37%; p=0.03) than did 12-core systematic biopsy in 152 patients with prostate-specific antigen levels <10 ng/mL [45]. Additionally, the cancer core length in targeted biopsy cores (median, 8 mm) was significantly higher than that in systematic biopsy cores (median, 4 mm; p<0.0001, n=152) [45].
In localization of csPCa in the prostate, concordance between the index lesion location on biopsy and radical prostatectomy specimens is 95%. A previous study investigated 135 patients who had cancer diagnosed with T2WI and DWI-ADC sequences on 1.5T or 3.0T MRI [29]. This study showed that concordance of the primary Gleason pattern between targeted biopsy and radical prostatectomy specimens was 90% based on the results of MRI-TRUS fusion image-guided biopsy.

4. Controversy in MRI-TRUS fusion image-guided prostate biopsy

1) Approach of the biopsy: transperineal or transrectal?

There are no clear recommendations regarding the transrectal or transperineal approach. For systematic TRUS-guided biopsy, cancer detection rates are comparable for both approaches [4647]. With regard to complications, the incidence rates of infection and rectal bleeding are higher with transrectal prostate biopsy than with the transperineal approach [48]. Furthermore, lesions that are located in the anterior part of the prostate, particularly in high-volume prostates, might be missed in transrectal prostate biopsy. Transperineal prostate biopsy usually ensures greater comfort of the patient. Previous studies have suggested that transrectal biopsy might have a higher risk of infection than the transperineal approach because fecal bacteria can enter the blood circulation after retrieving specimens from the prostate [49]. Transperineal biopsy has been reported to be more painful than transrectal biopsy [50]. Therefore, spinal anesthesia is performed for transperineal biopsy and thus it might not be suitable for outpatient procedures. However, few groups have reported the possibility of obtaining a transperineal biopsy under local anesthesia [51].
Tewes et al. [52] introduced the process of the decision for which biopsy approach to use (transperineal vs. transrectal) with BioJet. In this process, the approach was decided on the basis of the patient's wishes after detailed information of the risks and advantages of the transrectal and transperineal approaches [52]. Additionally, these authors considered that prostate size, tumor localization according to MRI, and the patients' general condition were important for the decision [52]. They achieved a high detection rate of PCa. They found that sensitivity/specificity for tumor detection with a PI-RADS category ≥4 were 81%/69% for transrectal biopsy and 86%/84% for transperineal biopsy [52]. Based on previous studies, a flexible choice of the biopsy approach is required depending on the patients' risk (e.g., poorly controlled case of diabetes mellitus, hemorrhoids), and the location and size of suspected cancer lesions on mpMRI.

2) Image registration in MRI and TRUS: elastic fusion vs. rigid?

Because elastic fusion compensates for possible deformation caused by insertion of the ultrasound probe into the rectum, it is expected to perform better than rigid registration. A systematic review and meta-analysis evaluated elastic versus rigid image registration in MRI-TRUS fusion image-guided prostate biopsy [53]. This analysis showed that the detection odds ratios for significant PCa were 1.45 (95% CI, 1.21–1.73; p<0.0001) and 1.40 (95% CI, 1.13–1.75; p=0.002) for the elastic and the rigid registration subgroups, respectively, and there was no significant difference between the subgroups (p=0.83). However, rigid registration requires cognitive optimization of registration, and accurate cognitive fusion should be performed after rigid software-assisted fusion. Therefore, rigid registration would be appropriate for experts in cognitive fusion, but not for those without this knowledge. Because there have been no prospective comparisons between elastic and rigid image registration, a randomized, prospective, comparative study is required to investigate this issue.

5. Prospects of tailor-made medicine of PCa by development of MRI-targeted biopsy

With development of MRI-targeted biopsy, high accuracy of detection and spatial location of csPCa has been achieved. This development has contributed to management of PCa, such as active surveillance, radical prostatectomy, and focal therapy. Active surveillance is a standard option for patients with low-risk PCa [54]. Currently, serum prostate-specific antigen kinetics [55] and pathological findings [56] of follow-up systematic biopsy are monitored in patients under active surveillance. A limitation of the present active surveillance is that prostate-specific antigen kinetics is not cancer-specific, with fluctuation by inflammation and mechanical manipulation. Additionally, systematic biopsy lacks reliability for predicting disease progression during active surveillance [56]. Therefore, image-based active surveillance has been reported. In a retrospective study of image-based monitoring of targeted biopsy-proven PCa in active surveillance, the potential of longitudinal monitoring of TRUS-visible biopsy-proven cancer was reported in an 11-year experience [57]. In multivariate analysis for predicting pathological progression, an increase of ≥25% in diameter of the biopsy-proven lesion (hazard ratio, 15.314; p=0.023) and an upgrade of Doppler grade (hazard ratio, 37.409; p=0.019) were significant risk factors [57]. Clinical studies of mpMRI-based active surveillance are ongoing because mpMRI is a promising risk stratification tool and should be considered for men on active surveillance [58]. In radical prostatectomy, the usefulness of real-time monitoring of TRUS-visible csPC lesions during robot-assisted radical prostatectomy has been reported [59]. A clinical study showed that three of four patients who were highly suspected as having capsule invasion achieved a negative surgical margin [59]. This was shown by real-time navigation of the TRUS-visible csPC location during robot-assisted radical prostatectomy.
Multi-focality of PCa has been reported to be as high as 80% [60]. However, recent evidence suggests that csPCa is the responsible lesion for disease progression [6162]. Therefore, treatment of csPCa would potentially achieve control of tumor progression. Based on the concept and development of diagnosis of csPCa, clinical trials of focal therapy have been conducted for localized PCa treatment [63]. The aim of focal therapy is to treat clinical significant cancer with minimal injury to the urethra, sphincter, neurovascular bundle, and bladder neck [64]. Although there have been a few clinical studies in Asia, only one prospective clinical trial of focal therapy with high-intensity focused ultrasound (HIFU) based on MRI-TRUS elastic fusion image-guided transperineal prostate biopsy has been reported [65]. Fig. 5 shows the treatment process of focal therapy for localized PCa with HIFU by a Japanese group.

CONCLUSIONS

MRI-TRUS fusion image-guided prostate biopsy achieves higher accuracy of detection and spatial location of csPCa compared with systematic biopsy. With development of biopsies, prostate management could progress to precise tailor-made medicine, such as active surveillance, radical treatment, and focal therapy.

Figures and Tables

Fig. 1

mpMRI of a representative case suspected with prostate cancer. mpMRI includes a combination of high-resolution T2WIs, DCE images, DWIs, and ADC. The lesion suspected as cancer was diagnosed in the anterior in transition zone (in the white arrows) on mpMRI, which was diagnosed as Prostate Imaging and Reporting and Data System category 5. mpMRI, multi-parametric magnetic resonance imaging; T2WI, T2-weighted image; DCE, dynamic contrast-enhanced; DWI, diffusion-weighted image; ADC, apparent diffusion coefficient. A 1.5Tesla magnet (Signa HDx) with an 8-channel cardiac coil.

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Fig. 2

Composition of MRI-TRUS fusion image-guided prostate biopsy. MRI-TRUS fusion image-guided prostate biopsy comprises image registration (rigid or elastic), the needle tracking method (electromagnetic tracking, mechanical position encoders, or image-based software tracking), and the route of biopsy (transperineal or transrectal). MRI-TRUS, magnetic resonance imaging-transrectal ultrasound.

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Fig. 3

Elastic fusion of MRI and TRUS. Three-dimensional information is transferred from mpMRI to TRUS of the prostate with elastic image fusion software. MRI, magnetic resonance imaging; TRUS, transrectal ultrasound; mpMRI, multi-parametric MRI.

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Fig. 4

Process of MRI-TRUS fusion image-guided prostate biopsy with BioJet version 2.0. (A) First, the operator marks the target point on the work station. Transperineal template coordinates are shown on the monitor. Biopsy simulation is performed in a 3D model of the prostate. (B) Transperineal template-assisted biopsy is then performed by viewing axial and sagittal real-time fusion 2D images of the prostate. For a difficult case of the template-assisted transperineal approach due to the pelvis, transperineal free-hand biopsy is performed by viewing axial and sagittal real-time fusion 2D images of the prostate. (C) After each biopsy, biopsy needle tracking is recorded in 2D and 3D fusion images of the prostate. 3D, three-dimensional; 2D, two-dimensional; TZ, transition zone; PZ, peripheral zone.

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Fig. 5

Process of focal therapy for localized prostate cancer with high-intensity focused ultrasound. MRI-TRUS elastic fusion image-guided transperineal biopsy is performed with the BioJet system. The recorded localization of mpMRI-visible csPCa is converted to the treatment planning screen of TRUS images on a workstation of the HIFU device (Sonablate 500). The treatment range is determined and csPCa is treated. Contrast-enhanced MRI is performed at 2 weeks after treatment for evaluation of the treatment effect. MRI-TRUS, magnetic resonance imaging-transrectal ultrasound; mpMRI, multi-parametric magnetic resonance imaging; 3D, three-dimensional.

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ACKNOWLEDGMENTS

This work was supported by the Takeda Science Foundation.
We thank Ellen Knapp, PhD, from Edanz Group (www.edanzediting.com/ac) for editing a draft of this manuscript.

Notes

CONFLICTS OF INTEREST The author has nothing to disclose.

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Sunao Shoji
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