Summary
Prostate cancer (PCa) is the most common cancer type in men. Overall, the goal of prostate-specific antigen (PSA)-based screening is to identify early-stage disease that can be treated successfully. However, evidence supporting an overall survival advantage in men undergoing PSA screening is controversial, leading to a lack of consensus on guidelines.
The present review article provides an overview of the most important studies on PSA screening including the latest updates of large trials. In addition, modern concepts in early detection of PCa that can be added to PSA measurement alone such as PSA isoforms or mpMRI are discussed. Lastly, recommendations for PCa screening and early detection from the European and German Societies of Urology issued in 2019 are presented.
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Introduction
Prostate cancer (PCa) is the most common cancer and remains an important cause of death in males [1]. Overall, PCa is a pleiotropic disease ranging from slow-growing organ-confined tumors to highly aggressive carcinomas associated with metastatic spread inducing significant morbidity and mortality. Although most type of prostate tumors belong to the slow-growing forms, 10–15% of patients are diagnosed in a metastatic stage of disease. Therefore, early detection is important in PCa treatment strategies.
Prostate-specific antigen (PSA) remains the most used biomarker in the detection of early PCa [2]. In general, PSA is a serine protease produced and released by epithelial cells of the prostate. It is secreted as an inactive proenzyme (proPSA) into seminal fluid and activated by the kallikrein-related peptidase 2 and other endopeptidases produced in the prostate. PSA itself occurs in several different molecular forms in serum: free PSA (fPSA) and complexed PSA (total PSA; [2, 3]).
Although it has been demonstrated in large patient cohorts that regular PSA measurement reduces PCa mortality rates, PSA screening is still a controversial issue in most countries because beside the benefits there are also harms such as overdiagnosis and overtreatment.
Impact of PSA measurement on mortality
The European Randomized Study of Screening for Prostate Cancer (ERSPC) was initiated in 1993 and is the world’s largest randomized controlled trial on PSA screening including men aged 55–69 years from eight European countries [4]. Data revealed a 21% reduction of PCa mortality after 11 years of follow-up in screened patients [4]; the 13-year follow-up update also confirmed that mortality was significantly lower in the screened group compared with the control group [5].
Recently, the 16-year follow-up of the ERSPC was published corroborating earlier results that PSA screening significantly reduces PCa mortality. In detail, the study was able to demonstrate a larger benefit with longer follow-up, reporting a rate ratio of PCa mortality of 0.80 (95% confidence interval [CI] 0.72–0.89, p < 0.001) at 16 years. The difference in absolute PCa mortality increased from 0.14% at 13 years to 0.18% at 16 years. The number of men that had to be invited for screening to prevent one PCa death was 570 at 16 years compared with 742 at 13 years. The number needed to diagnose was reduced to 18 from 26 at 13 years [6]. In addition, in July 2019 the study group published data excluding differential or better treatment in the screening arm compared with the control arm, which has been commonly suggested to bias PCa mortality in the ERSPC study [7]. However, there is also evidence that ERSPC centers varied by attendance, screening interval, biopsy compliance, contamination in the control arm, as well as treatments. Admittedly, using a microsimulation model, the ERSPC investigators were able to demonstrate that ERSPC would have shown only a slightly larger PCa mortality reduction if all centers had complied with the quality criteria for attendance or biopsy compliance [8]. These data again underline the importance of compliance to PSA testing as well as that biopsy after an elevated PSA substantially influences PCa mortality.
In contrast to the Swedish ERSPC data, the U.S. Prostate Lung Colorectal and Ovarian (PLCO) cancer screening trial randomized 76,685 men aged 55–74 years. Both PSA and digital rectal examination were used in the three first annual screens and PSA only (cut-off 4 μg/l) in the last two rounds. In contrast to the Swedish study, the incidence of PCa at 13 years was 108 per 10,000 person-years in the screening arm and 97 in the control arm (RR = 1.12, 95% CI: 1.02–1.17) failing to show any difference in PCa mortality between the screening and control arm [9]. An extended follow-up of the PLCO trial over a median of 15 years continued to indicate no reduction in PCa mortality for the intervention arm versus the control arm [10].
Besides the U.S. and the Swedish study, PSA testing was also introduced in Tyrol (Austria) in 1988, and since 1993 it has been offered cost free in an organized form to men aged between 45 and 74 years. In line with the ERSPC data, survival analyses revealed a significant reduction in PCa mortality with a risk ratio of 0.70 (95% CI: 0.57–0.87) for Tyrol compared with the mortality rate in the period from 1989 to 1993 in Austria [11, 12]. However, a significant problem of the Tyrol study was that more than 50% of diagnosed cancers were low risk, opening the discussion of overdiagnosis and overtreatment [13]. Thus, we recently evaluated the age-dependent PSA cut-offs used since 1995 in our early detection program in order to reduce the number of unnecessary biopsies in patients with benign disease, but without missing PCa, in particular without missing significant PCa [13]. With “new,” fine-tuned PSA cut-offs, we detect all relevant PCa with a significant reduction of biopsies compared with the “old” cut-off values, which is one step toward a smarter strategy in the Tyrol PCa Early Detection Program.
Additional parameters beyond PSA for PCa diagnosis
Molecular markers
A main limitation of PSA-based early PCa detection is its low specificity associated with a high proportion of men detected with nonmalignant findings at the first or subsequent prostate biopsy. Thus, several concepts to optimize PSA rating such as PSA density (PSA/prostate volume), PSA kinetics (velocity, doubling time), and age- or race-specific reference ranges have been described to reduce the false-negative and false-positive rates of PCa detection.
Moreover, one has to consider that 10–30% of PSA is present in an uncomplexed form, whose implementation in PSA measurement has further improved the accuracy of cancer detection compared with PSA alone [14]. For example, the use of percentage of free PSA (fPSA%) has been successfully demonstrated in numerous studies to improve the accuracy of PCa detection compared with PSA measurement alone. To summarize, studies revealed a lower ratio of fPSA/PSA in PCa patients compared with patients with benign prostate hyperplasia (reviewed in [15]). In addition, several studies identified the PSA isoform proPSA as a predictor of significant PCa [16,17,18]. Thereby studies including our own research were able to demonstrate that a high amount of proPSA is associated with aggressive forms of PCa [18,19,20,21].
Besides fPSA and proPSA, several concepts combining total PSA values with PSA isoforms have been developed to reduce the false-negative and false-positive rates of PCa detection. By way of example, prostate health index (PHI) calculation combines PSA, fPSA, and proPSA and now plays an important role in discriminating the presence of PCa from non-cancerous prostatic diseases [22, 23]. Incrementally, our own data described the PHI index as a marker of cancer aggressiveness and as a predictor of disease progression in patients undergoing active surveillance [21].
Secondary, multivariate prediction models, such as nomograms have been developed providing a more accurate method for prospectively determining the risk of a positive biopsy. Lastly, apart from PSA, numerous studies investigated new biomarkers for PCa detection among them some—for example, PCA3, 4KScore, or TMPRSS2-ERG—are highly promising; however, this topic is beyond the scope of this mini review article.
Multiparametric magnetic resonance imaging
Multiparametric magnetic resonance imaging (mpMRI) of the prostate is a novel promising tool for the diagnosis of PCa that might help to reduce overdiagnosis of insignificant cancer types.
According the current guidelines of the European Society of Urology (EAU), mpMRI should be used for patients with a previous negative prostate biopsy; however, the role of a mpMRI in biopsy-naive men remains conflicting. For example, it has been shown that in men with clinical suspicion of PCa, a subsequent positive MRI did not differ regarding overall PCa detection [24]. By contrast, the PROMIS trial showed that mpMRI-targeted biopsy had greater sensitivity than transrectal ultrasound(TRUS)-guided biopsy (87% vs. 60%) and a higher negative predictive value (NPV (72% vs. 65%) for detecting significant PCa [25].
Several studies are ongoing, or have been terminated, to investigate PCa prediction rates by combing mpMRI with PSA; among them, PSA density and PHI are the most commonly studied. For instance, Washino et al. reviewed 288 biopsy-naive patients who underwent mpMRI-guided prostate biopsy for suspected PCa for whom PSA density values were available and found that a high PI-RADS score in combination with a high PSA density (PI-RADS score ≥4 plus PSA density ≥0.15 ng/ml/ml, or PI-RADS score 3 plus PSA density ≥0.30 ng/ml/ml) yielded high PCa detection rates [26]. Druskin et al. showed that the addition of PHI to a multivariate model including age, biopsy history, and Prostate Imaging Reporting and Data System (PI-RADS) score increased the area under the curve for clinically significant PCa detection from 0.83 to 0.90 in a cohort of 109 patients [27].
Guideline recommendations—who to screen? When to start?
As not all large randomized clinical trials proved uniform survival advantages, screening for PCa is one of the most controversial topics in the urological literature. Based on this, there exist no consistent guidelines concerning PSA measurement. Overall, an individualized risk-adapted strategy for early detection might be offered to a well-informed man with at least 10–15 years of life expectancy. In addition, care should be taken to carefully identify the patient, taking into account the potential benefits and harms involved such as overdiagnosis and overtreatment of low-risk PCa.
An overview of the recommendations for PCa screening and early detection of the European (Table 1) and German Societies of Urology (Table 2) updated in 2019 are illustrated in Tables 1 and 2.
Conclusion
PCa is the most common cancer type in men. Overall, the goal of PSA-based screening is to identify early-stage disease. However, not all clinical trials were able to demonstrate a survival advantage in men undergoing PSA screening, thereby leading to a lack of consensus on guidelines. Thus, an individualized risk-adapted strategy should be pursued to balance the advantages and harms of PSA measurement.
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I. Heidegger declares that she has no competing interests regarding this manuscript.
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Heidegger, I. PSA screening—a matter of debate?. memo 12, 244–248 (2019). https://doi.org/10.1007/s12254-019-00524-9
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DOI: https://doi.org/10.1007/s12254-019-00524-9