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Objective To assess the value of free-hand transperineal multiparametric nagnetic resonance imaging/transrectal ultrasound (mpMRI/TRUS) fusion-guided targeted biopsy (TB) for the diagnosis of prostate cancer(PCa).Methods Patients with elevated PSA level and/or an abnormal DRE finding were recruited prospectively between January 2015 and September 2016.Patients were classified to various scores from 2 to 5 according to prebiopsy mpMRI PI-RADS.Based on free-hand transperineal mpMRI/TRUS fusion-guiding,a 2-cores TB for each cancer-suspicious lesion were carried out and followed 12-cores systematic biopsy (SB) protocol.Pathological findings of biopsy and radical prostatectomy (RP) specimens were analyzed.Results A total of 397 patients were enrolled in this study.The median age of the patients was (68.2 ± 7.4) years old,ranging 42-78 years.The median PSA level was (15.0 ±12.4)ng/ml,ranging 3.0-88.3 ng/ml.DRE showed abnormality in 28 patients(7.1%).The median prostate volume was (41.6 ± 16.4)cm3,ranging 24.6-89.8 cm3.The PCa detection rate of TB was significantly increased compared with SB (44.8 % vs.34.8%) (P =0.003),especially in clinically significant PCa (P < 0.001) and intermediate/high-risk PCa (P =0.003),respectively.Of the all 588 mpMRI targeted lesions,277 lesions were positive.A total of 105 index tumors were identified in RP specimens,the locations of TB-proven cancer showed 96.6% (85/88) in correspondence with the location of the index lesion in RP specimens.Conclusions Free-hand transperineal mpMRI/TRUS fusion-guided TB providing greater detection of intermediate-high risk PCa while limits over detection of low risk PCa.Moreover,TB can reliably predict the location of an index tumor.
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Objective To evaluate the value of transperineal targeted biopsy with real-time fusion images of transrectal ultrasound (TRUS)and multiparametric magnetic resonance imaging (mpMRI)for the diagnosis of prostate cancer (PCa).Methods Clinical and imaging data of 62 consecutive patients suspected of PCa at the mpMRI scan and PSA>4.0 μg/L were retrospectively analyzed.Targeted biopsies (TB)were carried out for each cancer-suspicious lesion,and followed a systematic 12-core biopsy (SB) protocol.Pathological findings of TB and SB were analyzed.Results The age of the patients was (68.38± 6.57)years (range 5 1 -79 years).The preoperative PSA value was (10.21 ±5.57)μg/L (range 4.5 -30.1μg/L).Preoperative prostate volume was (34.05±9.86)ml (range 19-64 ml).The PCa patients detected by SB and/or TB were 34 (54.8%).Cancer-detected rates of SB and TB cores were 7.53% and 26.2%, respectively (P <0.001).The positive core length of SB and TB cores were (3.71 ±2.77)mm (range 1 -14 mm)and (5.00±3.04)mm (range 2-1 7 mm),respectively (P =0.016).The positive core percent of SB and TB cores were (28.77 ± 20.13 )% (range 7 - 100%)and (35.76 ± 1 8.73 )% (range 1 1 % - 100%), respectively (P =0.048).Moreover,clinically cores detected by the SB and TB for final diagnosis of PCa were 19 cores (2.6%)and 48 cores (1 8.5%),respectively (P < 0.001 ).Conclusions Transperineal TB using real-time TRUS and mpMRI fusion imaging can improve sampling quality and elevate clinically detection rate of PCa when application combined with SB.
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PURPOSE: Recently multi-modal imaging system has become widely adopted in molecular imaging. We tried to fabricate animal-specific positioning molds for PET/MR fusion imaging using easily available molding clay and rapid foam. The animal-specific positioning molds provide immobilization and reproducible positioning of small animal. Herein, we have compared fiber-based molding clay with rapid foam in fabricating the molds of experimental animal. MATERIALS AND METHODS: The round bottomed-acrylic frame, which fitted into microPET gantry, was prepared at first. The experimental mice was anesthetized and placed on the mold for positioning. Rapid foam and fiber-based clay were used to fabricate the mold. In case of both rapid foam and the clay, the experimental animal needs to be pushed down smoothly into the mold for positioning. However, after the mouse was removed, the fabricated clay needed to be dried completely at 60 degrees C in oven overnight for hardening. Four sealed pipet tips containing [18F]FDG solution were used as fiduciary markers. After injection of [18F]FDG via tail vein, microPET scanning was performed. Successively, MRI scanning was followed in the same animal. RESULTS: Animal-specific positioning molds were fabricated using rapid foam and fiber-based molding clay for multimodality imaging. Functional and anatomical images were obtained with microPET and MRI, respectively. The fused PET/MR images were obtained using freely available AMIDE program. CONCLUSION: Animal-specific molds were successfully prepared using easily available rapid foam, molding clay and disposable pipet tips. Thanks to animal-specific molds, fusion images of PET and MR were co-registered with negligible misalignment.