A precise staging, local extent, and extra-prostatic metastasis are crucial in intermediate-risk and high-risk PCa patients for further treatment method decisions. These include radical prostatectomy (RP) with standard nodal dissection or extended pelvic lymph node dissection (ePLND) in PCa, radiotherapeutic treatment, or multimodal therapy. A prospective comparison of primary staging before and after PSMA-ligand PET/CT was conducted. Intermediate- and high-risk PCa patients (n = 108) have indicated that PSMA-ligand PET/CT upstaged 6.4% of patients from M0 to M1. Moreover, compared with conventional imaging, 14% of N0M0 patients became N1M0, and 2.8% of M1 patients ended up with M0. A change in management of the disease occurred in 21% of patients (18).

The additional molecular imaging information has increased the detection rate of PSMA-ligand PET/CT. As evidence increases, PSMA-ligand PET/CT is more effective in initial staging than other imaging modalities. Compared with traditional imaging modalities such as bone scans and CT, several studies have shown ⁶⁸Ga-PSMA-11 PET improved detection rates in malignant lesions (19). Several retrospective studies have shown that ⁶⁸Ga-PSMA-11 PET/CT is superior to standard imaging and has high sensitivity and specificity (94% and 99%, respectively) for lesion detection (12, 20). A recent prospective trial, proPSMA, demonstrated that the diagnostic accuracy of PET/CT was 27% greater than conventional imaging (p < 0.001) (21).

The high specificity and high sensitivity of PSMA-ligand PET in lesion detection of primary PCa patients have been proven. A retrospective study of 1,253 patients (high-risk, 47.6%), metastatic disease was detected by ⁶⁸Ga-PSMA-11 PET in 12.1% of the cohort. Nearly half of the detected lymph node metastases were outside the boundaries of an ePLND ( Figure 1 ). Skeletal metastases were found in 59 men (4.7%). PCa metastases were identified in 5.2% of intermediate-risk patients, compared with 19.9% of high-risk patients. The study highly demonstrated the potential of using PSMA-PET for primary staging (22). Another study comparing 340 segments from ⁶⁸Ga-PSMA-11 PET and multiparametric MRI with histopathology has revealed that ⁶⁸Ga-PSMA-11 PET/CT significantly outperformed multiparametric MRI and even better results were achieved when both methods were combined (23).

Furthermore, for detection of bony lesions in PCa, PSMA-ligand PET clearly outperformed standard imaging (CT, MRI, and bone scanning) in several studies (24, 25). Janssen et al. have reported a superior sensitivity and specificity of ⁶⁸Ga-PSMA-11 PET/CT compared with ^99mTc-3,3-diphospho-1,2-propanodicarboxylic acid (DPD), single-photon emission computed tomography (SPECT). In the region-based analysis, the sensitivity and specificity of ⁶⁸Ga-PSMA-11 PET/CT were 97.7% and 100%, respectively, and those of ^99mTc-DPD-SPECT were 69.4% and 98.3%, respectively (p < 0.05) (25). A study including 75 patients and 410 bone regions has demonstrated similar results. It has been proven that ⁶⁸Ga-PSMA-11 PET outperformed planar ^99mTc bone scintigraphy to detect affected bone regions (sensitivities and specificities for PET vs. ^99mTc bone scintigraphy [patient-based analysis]: 98.7%–100% vs. 86.7%–89.3%; 88.2%–100% vs. 60.8%–96.1%; [region-based analysis]: 98.8%–99% vs. 82.4%–86.6%; 98.9%–100% vs. 91.6%–97.9%; p < 0.001, respectively) (24). Interestingly, according to a systematic review of 12 studies and 322 patients who underwent ⁶⁸Ga-PSMA-11 PET scanning for primary stage disease, methodology and outcomes differed greatly. The median sensitivity and specificity were 33%–92%, 82%–100% per lesion and 82%–100%, 67%–99% per patient, respectively.

Several studies indicated that in most tumor diseases, the diagnostic performance of PET/MRI is similar to or even better than that of PET/CT (26). PET/MRI is widely utilized in PCa patients, primarily for its advantages in combining PET and MRI, providing high-resolution multiparametric imaging (27). PET/MRI is employed to delineate radiation therapy target areas (28) and diagnose BCRs (29), and for the preoperative assessment of high-risk patients (30). This technology has the potential to enhance the management and treatment decision-making for PCa patients, especially in complex cases, but further research is needed to validate its advantages.

Therefore, PSMA-ligand PET/CT or PET/MRI can be used to determine the extent of local tumors, lymph nodes, bone, and organ metastases, and, more importantly, to plan effective treatment and improve prognosis. However, published data on mechanism experiments and heterogeneous uptake of PSMA-ligand are still limited (31). Recent studies have demonstrated this using PSMA immunohistochemistry; nonetheless, PSMA ligands and antibodies have different sizes and binding positions, which may introduce methodological limitations. Further studies are needed before reliable conclusions can be drawn.

In approximately 30% to 40% of PCa cases, disease will recur after the primary treatment. Elevating levels of prostate-specific antigen (PSA) always indicate the recurrence (11). Because of the implications for future disease management, the location of the lesions must be determined once BCR has been detected. However, localizing lesions is a difficult task. There has been evidence that salvage radiotherapy in patients with BCR after RP is most effective while serum PSA <0.5 ng/mL (32, 33). Radiotherapy timing is crucial to these patients. Monitoring PSA cannot easily provide enough information.

Regarding conventional imaging modalities, CT can detect only 11%–14% of lesions in patients with BCR after RP (34). Compared with bone scans, choline-based PET imaging has higher pooled specificity [0.82, 95% confidence interval (CI) 0.78, 0.85; 0.99, 95% CI 0.93, 1.00, respectively] and reports fewer false-positive lesions (35). Moreover, the PSA level, kinetics, and morphology have significantly affected the sensitivity of choline PET (36–38).

However, PSMA-ligand PET shows a much higher detection rate, especially in low PSA levels. Afshar-Oromieh et al. assessed a large cohort including 319 patients with recurrent PCa who underwent ⁶⁸Ga-PSMA-11 PET (median serum PSA value of 4.59 ng/mL, range: 0.01–41395 ng/mL). They reported detection rates of 47% for serum PSA values ≤ 0.2 ng/mL, rising to 100% for serum PSA values > 20 ng/mL (39). Similar results from other studies have further proven that ⁶⁸Ga-PSMA-11 PET has higher detection rate for BCR with low PSA levels (40, 41). In addition, data from other research groups that studied ¹⁸F-DCFBC, ¹⁸F-DCFPyL, and ¹⁸F-rhPSMA-7 have also indicated rather high detection rates with low serum PSA levels ( Figure 2 ) (42–44).

However, these results should be treated with caution because there was no systematic histological confirmation in most of the patients, and follow-up imaging was incomplete in the entire cohort. Current guidelines do not make recommendation for a single radiopharmaceutical. The comparison among different PSMA-targeted tracers are missing; thus, the term “PSMA-ligand” refers to a number of different tracers (45). It is necessary to perform further clinical studies with standardized follow-up protocols and histological validation before comparing outcomes associated with the use of these tracers.

Androgen deprivation therapy (ADT) is the mainstay of treatment for PCa patients with recurrent or advanced disease (46, 47). However, in the first 5 years following ADT, approximately 10%–20% of patients will develop castration-resistant PCa (CRPC) (48). Once the metastatic castration-resistant prostate cancer (mCRPC) is detected, the overall survival (OS) ranges from 2 to 3 years (46, 47).

Monitoring the serum PSA level provides insight into both the disease burden and the biology of the disease; however, some mCRPC patients may have a low PSA level, because the tumor is less dependent on androgen receptor signaling. Moreover, PSA levels can stay low while visceral metastases are developing (49). The relationship between increasing PSA values and disease progression has been confirmed, but decreasing PSA values are not always associated with response to therapy. Using serum PSA alone to monitor disease development or therapy response in mCRPC patients is not entirely reliable (47, 50).

For mCRPC patients, some studies have suggested the choline PET/CT may be used in disease monitoring (51, 52). However, another prospective study has reported that there was no significant correlation between ¹¹C-choline PET/CT image findings and chemotherapy treatment response (53). In summary, the application of choline PET/CT appears to be limited to the routine monitoring of mCRPC patients.

It has been demonstrated that new tracers, such as ⁶⁸Ga-PSMA-11 PET/CT (54), can be used for monitoring disease in addition to choline, although these are not yet recommended in the mCRPC patient guidelines (45). Gafita et al. have reported a case of an mCRPC patient who underwent ¹⁷⁷Lu-PSMA therapy, and the ⁶⁸Ga-PSMA PET has clearly reflected the lesion alteration during the therapy (55). Thus, further studies in mCRPC patients are urgently needed to confirm the potential clinical application of PSMA-ligand in disease monitoring.

¹⁷⁷Lu-PSMA-617 is the most used beta-therapy molecule. The TheraP phase 2 trial reported that ¹⁷⁷Lu-PSMA-617 led to a higher PSA response rate (65/98 vs. 37/85) and fewer adverse events (32/98 vs. 45/85) as compared with cabazitaxel (15). Furthermore, the VISION trial has reported that compared with standard care, ¹⁷⁷Lu-PSMA-617 plus standard care significantly prolonged both imaging-based progression-free survival (median, 8.7 vs. 3.4 months; hazard ratio for progression or death, 0.40; 95% CI, 0.29, 0.57; p < 0.001) and OS (median, 15.3 vs. 11.3 months; hazard ratio for death, 0.62; 95% CI, 0.52 to 0.74; p < 0.001). Additionally, the quality of life was not affected by the adverse events caused by ¹⁷⁷Lu-PSMA-617 therapy (14). Another trial using LuPSMA reported that of 30 patients with mCRPC who had progressed after conventional treatment, 17 achieved a PSA decline of 50% or more. Fewer toxic effects and a reduction in pain were observed (16).

The other commonly used PSMA-ligand is ¹⁷⁷Lu-PSMA-I&T, which also shows promising results (57). In a study of 100 patients where ¹⁷⁷Lu-PSMA-I&T was used, a good response to treatment and low toxicity were observed (PSA decline ≥ 50%: 38 patients had a median clinical progression-free survival of 4.1 months and median OS was 12.9 months) (58). Several studies (59–61) have shown similar results (summarized in Table 1 ).

In addition, ¹⁷⁷Lu-PSMA-617 has been used in several types of combination therapies. In CRPC patients, the combination of androgen-receptor-axis-targeted therapies (ARATs) may lead to improved tumor control. The DNA damage repair (DDR) pathway has been proven to participate closely during the radioligand therapy (RLT) (62); hence, the combination with PARP inhibitors such as olaparib and rucaparib have been under analysis. Moreover, immune checkpoint inhibitors such as anti-PD-1 or anti-CTLA-4 monoclonal antibodies are an important class of cancer therapies. Owing to the abscopal effect, combination therapy is under evaluation. Table 2 summarizes representative clinical trials of combination therapies.

There are other notable PSMA-targeting radionuclide therapy agents. ¹³¹I-MIP-1095 is one of the first agents used in radiopharmaceutical therapy against PCa (63). A study of 34 mCRPC patients who received ¹³¹I-MIP-1095 found that the first dose of RLT presented with the best therapeutic effect compared with the second and the third doses (64). ¹⁷⁷Lu-PSMA-R2 is a urea-based PSMA-targeting small-molecule inhibitor (63). It has been shown to present a rapid tumor uptake and elimination through the urinary system in preclinical studies (65). A phase 1/2 clinical trial to evaluate ¹⁷⁷Lu-PSMA-R2 in mCRPC is currently under way (NCT03490838).

Utilizing alpha emitters for treatment offers two distinct advantages compared to conventional radioligand therapies. The short distance between cells within human tissue (<0.1 mm) allows the selective destruction of target cancer cells while preserving the surrounding healthy tissue (66). The two most commonly used alpha-emitting radioactive isotopes currently are ²²⁵Ac and its daughter nuclide ²¹³Bi, with half-lives of 9.9 days and 46 min, respectively.

Recent studies have demonstrated the remarkable efficacy of ²²⁵Ac-PSMA-617 in the treatment of mCRPC, particularly in patients who have experienced disease progression after ¹⁷⁷Lu-PSMA therapy (67). There is also a clinical case report of 213Bi-PSMA-617, which is both an alpha and beta emitter, that achieved a drop in PSA from 237 μg/L to 43 μg/L in the patient with mCRPC (68). The study by Sathekge et al. (69) involved a relatively small cohort of 21 patients, and confirmed that ²²⁵Ac-PSMA-617 can lead to a significant reduction of pre-treatment PSA levels by more than 50% in the majority of hormone-sensitive prostate carcinoma (mHSPC) patients.

However, the use of high-activity ²²⁵Ac/²¹³Bi generators for preparing therapeutic doses in the gigabecquerel (GBq) range remains prohibitively expensive, and the global supply of ²²⁵Ac produced from ²²⁹Th is severely limited (66). In terms of treatment, due to its highly cytotoxic nature, alpha-emitting isotopes like ²²⁵Ac may be associated with more serious side effects compared with PSMA-targeted β-radiation, including conditions like xerostomia (70). Furthermore, ²²⁵Ac produces a substantial number of recoiling daughter nuclei during its decay process, making this radioisotope challenging to control as a targeted alpha therapy agent (71). Nonetheless, this form of treatment offers hope for mCRPC and mHSPC patients and underscores the significant potential that targeted alpha therapy may have in the treatment of other cancers.

There are several anti-PSMA radioimmunotherapies under evaluation, with a notable example being the J591 antibody. ¹⁷⁷Lu-J591, ²⁵⁵Ac-J591, and ²²⁷Th-PSMA-TTC are three promising antibodies also under evaluation. The preliminary results using J591 show high efficacy and few side effects (72). The related clinical trials are listed in Table 1 .

PSMA-targeted bispecific T-cell engager (BiTE) immunotherapy has been developed in recent years. Pasotuxizumab (AMG 212) binds to CD3 on T cells and PSMA on the tumor cells. A phase I clinical trial (NCT 01723475) has shown that a PSA decrease ≥ 50% was observed in 3 out of 16 patients and that BiTE immune therapy could be efficacious in solid tumors (73).