PREDICTIVE VALUE OF PSA VELOCITY OVER EARLY CLINICAL AND PATHOLOGICAL PARAMETERS IN PATIENTS WITH LOCALIZED PROSTATE CANCER WHO UNDERGO RADICAL RETROPUBIC PROSTATECTOMY
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CARLOS A.L. MARTINEZ, MARCOS DALL’OGLIO, LUCIANO NESRALLAH, KÁTIA M. LEITE, VALDEMAR ORTIZ, MIGUEL SROUGI

Division of Urology, Paulista School of Medicine, Federal University of São Paulo (UNIFESP), São Paulo, SP, Brazil

ABSTRACT

     Objectives: To analyze the behavior of the prostate specific antigen velocity (PSAV) in localized prostate adenocarcinoma.
     Materials and Methods: We conducted a retrospective study of 500 men who had localized prostate adenocarcinoma, who underwent radical retropubic prostatectomy between January 1986 and December 1999. The PSAV was calculated for each patient and subsequently, the values were correlated with 5 groups: age, initial PSA value, clinical stage, tumor volume and Gleason score.
     Results: The behavior of PSAV presented statistic significance with an increment between 1.3 ng/mL and 9.6 ng/mL, ranging from 38.6% and 59.8% when compared with the initial PSA value (p < 0.0001), clinical stage (p = 0.0002), tumor volume (p < 0.0001) and Gleason score (p = 0.0009).
     Conclusion: PSAV up to 2.5 ng/mL/year is associated with factors of good prognosis, such as initial PSA below 10 mg/mL, clinical stage T1, tumor volume below 20% and Gleason score lower than 7.

Key words: prostate-specific antigen; prostatic neoplasms; pathology; neoplasm staging
Int Braz J Urol. 2004; 30: 12-7

INTRODUCTION

     Prostate cancer (PCA) is the most common cancer in males from Europe, North America and some African countries, occurring in 9.7% of all cancers in males, reaching 15.3% in developed countries and 4.3% in developing countries (1). Data from the Brazilian National Cancer Institute (http://www.inca.gov.br/estimativas/2003/index.asp?link=tableestados.asp&UF=BR) estimate that, in 2003, 35,200 new cases of PCA will be diagnosed and 8,200 men should die as a consequence of it.
     The most commonly used methods for detecting PCA are the digital rectal examination, the transrectal ultrasonography of the prostate and the prostate-specific antigen (PSA). The digital rectal examination has a sensibility between 40 and 80%, specificity of 55% and a positive predictive value between 17 and 45% (2). Transrectal ultrasound (TRUS) reaches detection rates between 2.3 and 14.6% with positive predictive value between 17 and 36%, however, it presents low sensibility and specificity (3). Currently, the PSA is the main diagnostic test for PCA, being used for screening, prognosis, staging and cure control (4), however, the PSA is not an ideal marker, because it has a false positive index of 10 to 40% and positive predictive value of 46% (5). On the other hand, up to 20% of patients with prostate cancer have normal PSA (6).
     Since the dosing of serum PSA is accompanied by failure, variants of PSA measurements were described in order to increase its accuracy: The free/total PSA ratio (7), age-specific PSA (8), PSA density (9) and PSA velocity (psaV) (10,11).
     The objective of this work is to determine the behavior of PSAV according to age, initial PSA value, clinical stage, tumor volume and Gleason score, in patients who underwent radical prostatectomy due to localized prostate adenocarcinoma.

MATERIALS AND METHODS

     We conducted a retrospective, non-controlled, study based on the review of records from patients who underwent radical prostatectomy between January 1986 and December 1999. The patients included in this study were assessed and treated at São Paulo Hospital, from the Federal University of São Paulo, and Syrian Lebanese Hospital, São Paulo.
     The study comprised 500 patients, with diagnosis of localized prostate cancer in stages T1c, T2a, T2b, T2c and T3a, who underwent radical retropubic prostatectomy (RRP) between 1986 and 1999, with ages ranging from 42 to 76 years with a mean age of 62.4 years.
     For inclusion in the study, there was the requirement of at least 2 PSA values previously to diagnosis with an interval not lower than 6 months between both samples.
     Exclusion criteria were previous prostatic surgery, prostatitis or urinary infection at the moment of any PSA measurement (Hybritech Tandem-R e Abbott Imx).
     Surgical specimens (prostate, seminal vesicles and lymph nodes) were evaluated by the same pathologist (KML), analyzing the following pathological parameters: histological grade, tumor volume, surgical margins, infiltration of extra-prostatic tissue, infiltration of seminal vesicles, lymph nodes metastases and pathologic stage of disease.
     In order to calculate the PSAV, the patients were divided in 5 groups:
     Group I = PSAV / Age – A) 40-49, B) 50-59, C) 60-69, D) < 70;
     Group II = PSAV / Initial PSA value – A) 0-4, B) 4.1-10 C) 10.1-20 D) < 20
     Group III = PSAV / Clinical stage - T1a-b-c, T2a-b, T2c-T3;
     Group IV = PSAV / Tumor volume (cc) – A) 0-20, B) 20-50, C) < 50;
     Group V= PSAV / Gleason score – A) 2-3-4-5-6, B) 7-8-9-10.

Evaluation Criteria
     The PSAV was calculated for each patient by the method of regression curve analysis in units/time and percentage/time.

Statistical Analysis
     Non parametric tests were used; for 2 variables, we used the Mann-Whitney test and for 3 or more variables, we used the Kruskal-Wallis test. The p value < 0.05 was considered statistically significant.

RESULTS

PSAV / Age in Years
     No statistically significant differences were found in PSAV between different age groups. The majority of patients under study (81%) were in the range of 50-70 years (Table-1).



PSAV / Initial PSA Value
     We found statistically significant differences in PSAV when PSA was < 10 ng/mL. The PSA velocity reached 2.3 ng/mL when PSA < 10 ng/mL, however, when PSA was higher than 10 ng/mL its velocity was higher than 5 ng/mL (Table-2).



PSAV / Clinical Stage
     We found statistically significant difference in PSAV when confronting clinical stage T1 with T2c-T3a, according to PSA results in different stages of disease, with the mean PSA in T1c tumors being equal to 3.5 ng/mL, while in T2c-T3a tumors the mean reached 6 ng/mL (Table-3).



PSAV / Tumor Volume
     We found statistically significant difference in PSAV when the tumor volume was < 20% of the gland when compared to volumes between 21 – 50% and > 50 (Table-4).



PSAV / Gleason Score
     We found statistically significant differences in PSAV between the 2 groups (Table-5).

DISCUSSION

     Our results show that the behavior of PSAV compared to its initial value, clinical stage, tumor volume and Gleason score, present a significant variation in PSAV with an increment between 1.3 ng/mL and 9.6 ng/mL, ranging from 38.6% to 59.8%.
     The difficulties for calculating the PSAV include its physiological variations between different tests, and the fact that PSA is not prostate cancer specific, limits its use, however, it is believed that PSAV has its maximal use for indicating biopsy for those patients with normal PSA or repeating the biopsy in cases of abnormal PSA (12).
     Roehrborn et al. (13) studied the variability of PSA in less than 90 days, in 295 patients having BPH with PSA values below 10 ng/mL, and found variations from 5.3 to 7.5 ng/mL between both PSA measurements. Additionally they found 19% of patients with an increment higher than 0.75 ng/mL, concluding that the PSA variability in a short time interval is statistically significant.
     An important study (14) compared the PSAV in patients with BPH and PCA and verified that the velocity was similar until 5 years before the diagnosis, however, between 7 and 9 years before the diagnosis the PSAV was higher in PCA. PSAV < 0.75 ng/mL/year was detected 2.6 years before the diagnosis in 72% of PCA cases, showing higher accuracy with PSA < 4.0 ng/mL, increasing the specificity from 60% to 90% (14). Our study revealed that all patients had a PSAV higher than 1.3 ng/mL/year, almost twice the value found by Carter et al. (14). Maybe the explanation for such differences is due to the size of the sample, since Carter et al. (14) worked with a group of 11 patients with clinically localized carcinoma, and our study group included 500 patients with clinically localized carcinoma.
     Smith & Catalona (10) determined a PSAV above 0.75 ng/mL/year, as being the point of highest sensibility (79%) and specificity (66%) for detecting prostate cancer in those patients with initial PSA lower than 4 ng/mL and under 70 years old. For initial PSA higher than 4 ng/mL the cut-off point of highest sensibility and specificity for detecting cancer was PSAV of 0.4 ng/mL/year or more (10). Another study (15) identified different values, finding a PSAV of 0.6 ng/mL/year for patients with initial PSA lower than 4 ng/mL, and 1.0 ng/mL/year for patients with initial PSA value higher than 4 ng/mL, in a group of 2,999 patients followed during 5 years for PCA screening.
     Another study (16) with patients showing PSA between 2.5 and 4 ng/mL, diagnosed BPH and PCA by calculation of PSAV, being 0.38 ng/mL/year and 0.52 ng/mL/year for BPH and PCA respectively, additionally it showed a higher PSAV in younger patients. In contrast, our study revealed PSAV of 59% and 1.3 ng/mL/year in the group of patients with PSA lower than 4,0 ng/ml. Our results did not show statistically significant differences concerning age.
     Thiel et al. (17) analyzed the PSAV and its role in the final pathologic prediction of PCA. They detected a PSAV value of 1.1 ng/mL/year for localized disease, and 1.9 ng/mL/year for non-confined disease.
     We observed that there is variability in the literature regarding the sensibility and specificity of PSAV, with values from 55% to 79% and 66% to 96% (11,13,18) respectively.
     When the PSAV was higher than 0.75 ng/mL/year the diagnosis of PCA was 47 to 70% (14), however, when the PSA is lower than 4 ng/mL, the prostate biopsy is indicated when PSAV is lower than 20% per year (19). In comparison to our results, all patients with PSAV higher than 1.3 ng/mL/year and higher than 38.6% correlated to the diagnosis of prostate cancer.
     Finally Schmid et al. (20) when studying 43 patients with untreated PCA, confirmed the doubling time of PSA through sequential measurements, and found that those patients with adverse factors showed a doubling time significantly shorter than those with favorable prognostic factors (24 versus 48 months in average). Such data can be applied to our results; if we analyze the PSAV values correlating them with factors that are associated with a good prognosis, we can observe that generally those patients with favorable elements such as low initial PSA, impalpable tumors, low Gleason and smaller tumors, have PSAV about 2.5 ng/mL/year.
     One critic to the present study, would be the difficulty of working with PSAV due to the test’s large variability, caused mainly by physiological variations and by the discrepancy between the different tests employed.
     Definitively it is impossible to reach a 100% level of sensibility and specificity with PSA, even if we create an ultra-sensitive PSA we will be able to reach the ideal level. This is valid for PSAV as well.
     Since this is the only available work on the behavior of PSAV in patients with localized prostate cancer including an expressive number of patients, it is necessary to perform prospective and randomized studies in order to confirm such findings.

CONCLUSION

     A low PSAV (about 2.5 ng/mL/year) was associated with factors of good prognosis such as initial PSA lower than 10 ng/mL, clinical stage T1, tumor volume lower than 20% and Gleason score lower than 7, not changing with age.

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Received: November 24, 2003
Accepted after revision: February 13, 2004

_______________________
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Dr. Marcos Dall’Oglio
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