Stesura Seveso


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31

ORIGINAL PAPER

ber of systematic needle cores and the best imaging pro-
cedure to use for omitting or postponing scheduled
repeated biopsies; in this respect, Multiparametric
Magnetic Resonance Imaging (mpMRI) is strongly recom-
mended in AS follow up (4, 5). 
Recently, Prostate-specific membrane antigen (PSMA)
inhibitors conjugated with the radionuclides 68Gallium
(68Ga) and 18fluoride (18F) have been well-explored and
successfully translated for the clinical diagnosis of PCa (6,
7). Moreover, tumour uptake, which represents PSMA
expression (standardised uptake value “SUVmax), resulted
highly correlated with the Gleason score of the primary
prostatic tumour (9). However, a limited number of stud-
ies have focused on the primary prostatic lesion (8, 9).
68Ga-PSMA positron emission tomography/computed tomog-
raphy (PET/CT) has shown to be sensitive for the detec-
tion of primary prostatic lesions and regional lym-
phadenopathy (10, 11). Recently, the use of 68Ga-PSMA
PET/CT combined with mpMRI has been suggested to
improve the accuracy to identify men suitable for active
surveillance (12).
The aim of this study is to prospectively evaluate the diag-
nostic accuracy of 68Ga-PSMA PET/CT in the diagnosis of
csPCa (Grade Group ≥ 2) (13) in men enrolled in AS pro-
tocol. 

MATERIALS AND METHODS
From May 2013 to December 2021 200 men aged
between 52 and 74 (median age 63) with very low risk
PCa were enrolled in an AS protocol study. After institu-
tional review board and ethical committee approval were
granted, informed consents were obtained from all par-
ticipants included in the study. Presence of the following
criteria defined eligibility: life expectancy greater than 10
years, clinical stage T1c, PSA below 10 ng/ml, PSA densi-
ty (PSA-D) < 0.20, ≤ 2 unilateral positive biopsy cores,
Gleason score 6/International Society of Urologic Pathology
(ISUP) Grade Groups (GG) 1, maximum core percentage
of cancer (GPC) ≤ 50% (3). All the patients underwent
confirmatory biopsy 6-12 months later the PCa diagnosis
previous mpMRI evaluation. During the follow up 48/200
(24%) men were upgraded and 10/200 (5%) men
autonomously decided to leave the AS protocol. After five

Introduction: To evaluate the accuracy of
68Ga-prostate specific membrane antigen

(PSMA) positron emission tomography/computed tomography
(PET/CT) in the diagnosis of clinically significant prostate can-
cer (csPCa: Grade Group ≥ 2) in men enrolled in Active
Surveillance (AS) protocol. 
Materials and methods: From May 2013 to December 2021 200
men aged between 52 and 74 years (median age 63) with very
low risk PCa were enrolled in an AS protocol study. During the
follow up 48/200 (24%) men were upgraded and 10/200 (5%)
decided to leave the AS protocol. After five years from confirma-
tory biopsy (range: 48-60 months) 40/142 (28.2%) consecutive
patients were submitted to mpMRI and 68Ga-PSMA PET/CT
imaging examinations before scheduled repeated biopsy. All the
mpMRI (PI-RADS ≥ 3) and 68Ga-PET/TC standardized uptake
value (SUVmax) ≥ 5 index lesions underwent targeted cores
(mpMRI-TPBx and PSMA-TPBx) combined with transperineal
saturation prostate biopsy (SPBx: median 20 cores). 
Results: Multiparametric MRI and 68Ga-PSMA PET/CT showed
18/40 (45%) and 9/40 (22.5%) lesions suspicious for PCa.  In
3/40 (7.5%) men a csPCa (GG2) was found; 68Ga-PSMA-TPBx
vs. mpMRI-TPBx vs. SPBx diagnosed 2/3 (66.6%) vs. 2/3
(66.6%) vs. 3/3 (100%) csPCa, respectively. In detail, mpMRI
and 68Ga-PSMA PET/TC demonstrated 16/40 (40%) vs. 7/40
(17.5%) false positive and 1 (33.3%) vs. 1 (33.3%) false negative
results. 
Conclusion: Although 68PSMA PET/CT did not improve the
detection for csPCa of SPBx (1 false negative result equal to
33.3% of the cases), at the same time, would have spared 31/40
(77.5%) scheduled biopsies showing a better diagnostic accuracy
in comparison with mpMRI (83.3% vs. 70.2%).

KEy wORDS: Prostate cancer; 68Ga-PSMA PET/CT; Active
Surveillance; PCa.

Submitted 18 March 2023; Accepted 28 March 2023  

INTRODUCTION
Active surveillance (AS) has become an alternative to radi-
cal treatment of low/very low risk prostate cancer (PCa),
reducing the risk of overtreatment and improving quality
of life of the patients (1-3). However, the time of confir-
matory biopsy has been established within one year from
initial diagnosis (4) there are no data regarding the num-

68Ga-PSMA PET/CT evaluation in men enrolled 
in prostate cancer Active Surveillance 

Pietro Pepe 1, Ludovica Pepe 1, Marinella Tamburo 2, Giulia Marletta 2, Francesco Savoca 1, 
Michele Pennisi 1, Filippo Fraggetta 3

1 Urology Unit, Cannizzaro Hospital, Catania, Italy; 
2 Radiotherapy Unit, Cannizzaro Hospital, Catania, Italy;
3 Pathology Unit, Cannizzaro Hospital, Catania, Italy.

DOI: 10.4081/aiua.2023.11322

Summary



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P. Pepe, L. Pepe, M. Tamburo, G. Marletta, F. Savoca, M. Pennisi, F. Fraggetta

32

years from confirmatory biopsy (range: 48-60 months),
also in the presence of stable clinical parameters, the last
40/142 (28.2%) consecutive patients were submitted to
mpMRI and 68Ga-PET/CT imaging examinations before
scheduled repeated biopsy. 
All mpMRI examinations were performed using a 1.5 or
3.0 Tesla scanner, equipped with surface 16 channels
phased-array coil placed around the pelvic area with the
patient in the supine position; multi-planar turbo spin-
echo T2-weighted (T2W), axial diffusion weighted imaging
(DWI) and axial dynamic contrast enhanced (DCE) were
performed for each patient. The mpMRI lesions charac-
terized by Prostate Imaging Reporting and Data System (PI-
RADS) version 2 (4) scores ≥ 3 were considered suspi-
cious for cancer; two radiologists blinded to pre-imaging
clinical parameters evaluated the mpMRI data separately
and independently; moreover, one urologist with more
than 25 years of experience performed the biopsy proce-
dure (4). 
PET/CT imaging was performed using a CT-integrated PET
scanner (Biograph 6; Siemens, Knoxville, TN, USA). 68Ga-
PSMA was prepared with a fully automated radiopharma-
ceutical synthesis device based on a modular concept
(Eckert & Ziegler Eurotope, Berlin, Germany). 68Ga-PSMA-11
was given to patients via an intravenous bolus (mean, 144
± 12 MBq; range, 122-188 MBq), and the PET acquisition
was started at a mean of 58 ± 12 min (range, 50-81 min)
afterward. Scans were acquired in 3-dimensional mode
with an acquisition time of 3 min per bed position.
Emission data were corrected for randoms, dead time, scat-
ter, and attenuation and were reconstructed iteratively
using ordered-subsets expectation maximization (4 itera-
tions, 8 subsets) followed by a postreconstruction smooth-
ing gaussian filter (5 mm in full width at half maximum).
For attenuation correction, a low dose unenhanced CT
scan was performed from the skull base to the middle of
the thigh. Images were processed to obtain PET, CT, and
PET-CT fusion sections in the axial, coronal, and sagittal
planes with a thickness of approximately 0.5 ~ cm by two
experienced nuclear medicine specialists, who were blind-

ed to the clinical data. The location of focal
uptake on 68Ga-PSMA PET/TC (Figure 1),
three-dimensional size, and SUVmax values
were reported on a per-lesion basis with a sex-
tant scheme (apex, midgland, and base, each
split into left and right) (4).
All the mpMRI (PI-RADS score ≥ 3) and 68Ga-
PET/TC index lesions (SUVmax ≥ 5) (14)
underwent cognitive targeted cores (mpMRI-
TPBx and PSMA-TPBx: four cores) combined
with saturation prostate biopsy (SPBx: median
20 cores; range 18-22). The procedure was
performed transperineally using a tru-cut 18
gauge needle (Bard; Covington, GA, USA)
under sedation and antibiotic prophylaxis
(15). The prostate targeted cores were done
using an Hitachi 70 Arietta ecograph, Chiba,
Japan) supplied by a bi-planar trans-rectal
probe (16) performing a free-hand cognitive
approach. 

RESULTS
The clinical parameters of the 40 men enrolled in Active
Surveillance protocol are listed in Table 1. 
Multiparametric MRI and 68Ga-PSMA showed 18/40
(45%) and 9/40 (22.5%) lesions suspicious for PCa those
were submitted to targeted cores combined with SPBx. In
detail, mpMRI PI-RADS score resulted ≤ 2 vs. 3 vs. 4 in 22
(55%) vs. 15 (37.5%) vs. 3 (7.5%) men. The average
intraprostatic SUVmax and tumor dimension was 4.6 g/mL
(range: 3.2-19.8) and 7.0 mm (range 4-12 mm), respec-
tively; only 9/40 (22.5%) men had a SUVmax ≥ 5 (range:
5.1-19.8), moreover, 68Ga-PSMA PET/TC showed two sus-
picious areas in correspondence of iliac ala and spinal cord
those resulted negative for metastases at targeted MRI for
bone evaluation. In 3/40 (7.5%) men a csPCa (GG2) was
found: both patients had a GPC equal to 20% with a num-
ber of positive cores equal to 3 and 4, respectively, more-
over PSA density was 0.15, 0.16 and 0.18, respectively. 
68Ga-PSMA-TPBx vs. mpMRI-TPBx vs. SPBx diagnosed
2/3 (66.6%) vs. 2/3 (66.6%) vs. 3/3 (100%) csPCa,
respectively. In detail, mpMRI and 68Ga-PSMA PET/TC

Table 1. 
Clinical parameters of 40 men enrolled in Active Surveillance
protocol submitted to scheduled biopsy.

Figure 1. 
68Ga-prostate-specific membrane antigen (PSMA) PET/CT: presence of high
vs. low suspicious area of clinically significant prostate cancer in the right (A)
vs. left lobe (B) of prostate gland (axial valuation) with a standardized uptake
value (SUVmax) equal to 88.8 vs. 6.5, respectively.
A. B.

Clinical and biopsy findings GG1 40 patients

Median PSA (range: 4.5-12.5 ng/ml) 4.8

Median PSA density (range: 0.10-0.20) 0.15

Median GPC (range: 10-50%) 40%

Median number of positive cores 2
Percentage of positive cores  98%

mpMRI 18
PI-RADS score ≥ 3 (45%)
68Ga-PSMA PET/CT 9
suspicious for PCa (22.5%)

GG: International Society of Urological Pathology Grade Group; mpMRI: multiparametric magnetic resonance imaging; 
PSA: prostate specific antigen; GPC: greatest percentage of cancer; PSMA: Prostate specific membrane antigen; 
PI-RADS: Prostate imaging reporting and data system; PET/TC: positron emission tomography/computed tomography.



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33

68Ga-PSMA PET/CT and Active Surveillance

demonstrated 16/40 (40%) vs. 7/40 (17.5%) false positive
and 1 (33.3%) vs. 1 (33.3%) false negative results; in
detail, one patient had PI-RADS score 2 and SUVmax of
6.8 and the second patient had PI-RADS score 3 and
SUVmax equal to 4.5 g/mL. In addition, mpMRI and
68Ga-PSMA PET/TC showed a diagnostic accuracy in the
diagnosis of csPCa equal to 70.2 and 83.3%, respectively.

DISCUSSION
The estimated risk-free treatment at 15 years in men
enrolled in AS with GG1 PCa is equal to 58% (1).
Although mpMRI is strongly recommended in the revalu-
ation of men in AS (2, 5, 6), still today, scheduled sys-
tematic repeated prostate biopsies are recommended to
reduce the false negative rate for csPCa of mpMRI equal
to 15-20% of the cases (16); At the same time, the num-
ber of cores performed at initial and repeat evaluation is
directly correlated with a lower risk of reclassification (6)
during the follow up allowing to postpone scheduled
repeated prostate biopsy in favour of clinical findings
(i.e., PSA density, risk calculator) (17-19) and imaging
revaluation (mpMRI) (5, 6). 
In the last years, 68Ga-PSMA-PET/CT has been suggested
to improve the clinical staging of high-risk PCa and dis-
ease recurrence (20, 21); at the same PSMA PET/CT has
been proposed for the diagnosis of primary intraprostatic
cancer (22, 23). The presence of focal uptake on PSMA-
PET/CT (SUVmax) and the maximal dimensions of PET-
avid lesions have been correlated with the presence of
csPCa (24, 25). There is a range of proposed cut-offs to
detect csPCa from SUVmax 3.15 to up SUVmax 9.1 (26,
27); the concordance between preoperative PSMA
PET/TC evaluation (SUVmax, dimension of the lesion)
and definitive prostate specimen ranges from 81.2% (28)
to 96% (29); moreover, PSMA PET/MRI seems reduce
false positive rate of PET/CT (about 8% of cases) (30). 
In our series, 68Ga-PSMA-TPBx vs. mpMRI-TPBx vs. SPBx
diagnosed 2/3 (66.6%) vs. 2/3 (66.6%) vs. 3/3 (100%)
csPCa, respectively. In detail, mpMRI and 68Ga-PSMA
PET/TC demonstrated 16/40 (40%) vs. 7/40 (17.5%) false
positive and 1 (33.3%) vs. 1 (33.3%) false negative
results. In addition, mpMRI and 68Ga-PSMA PET/TC
showed a diagnostic accuracy in in the diagnosis of csPCa
equal to 70.2 and 83.3%, respectively. In definitive, still
today, diagnostic imaging should not replace scheduled
prostate biopsy but is mandatory to detect targeted
lesions suspicious for csPCa; in addion, several biochem-
ical parameters, such as germline evaluation or PHI
(prostate health index), could be helpful in decrease the
ratio of scheduled biopsy.
Among our results some considerations should be made.
First, the number of patients evaluated was low. Secondly,
the results should be evaluated in the entire prostate spec-
imen and not in biopsy histology; a more detailed histo-
logical evaluation of patients who underwent biopsy
upstaging would be of interest, for example by adding sup-
plementary staining for PSMA on the biopsy samples.
Third, the low rate of reclassification (7.5% of the cases)
could be explained because the patients previously under-
went SPBx plus mpMRI evaluation before confirmatory
biopsy. Four, 68Ga-PSMA PET/TC evaluation could be pro-

posed in men with negative mpMRI or in the presence of
claustrophobia, severe obesity or cardiac pacemaker (13);
moreover, a 68Ga-PSMA PET/TC fusion platform would
have increased the accuracy of targeted prostate biopsy.
In conclusion, although 68PSMA PET/CT did not improve
the detection for csPCa of SPBx (1 false negative result
equal to 33.3% of the cases), at the same time, would
have spared 31/40 (77.5%) scheduled biopsies showing a
better diagnostic accuracy in comparison with mpMRI
(70.2% vs. 83.3%).

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Correspondence
Pietro Pepe, MD (Corresponding Author)
piepepe@hotmail.com
Ludovica Pepe, MD 
ludopepe97@gmail.com 
Francesco Savoca, MD 
Michele Pennisi, MD
michepennisi2@virgilio.it  
Urology Unit, Cannizzaro Hospital
Via Messina 829, Catania, Italy

Marinella Tamburo, MD 
marinellatamburo@virgilio.it
Giulia Marletta, MD 
marlettagiulia1@gmail.com 
Radiotherapy Unit, Cannizzaro Hospital, Catania, Italy

Filippo Fraggetta, MD 
filippofra@hotmail.com
Pathology Unit, Cannizzaro Hospital, Catania, Italy 

Conflict of interest: The authors declare no potential conflict of interest.