Abstract
Prostate-specific membrane antigen (PSMA) is of considerable interest as a target for diagnostics and therapy of prostate cancer patients. PSMA-targeted imaging has demonstrable value in guiding the management of the clinical evolution of prostatic cancer. The use of PSMA-targeted therapy using 177Lu-labeled PSMA-617 is similarly effective and is progressing toward approval. The phase III VISION trial represents the largest well-designed and executed study of a theranostic pair. This article provides an overview of the phase III trial and delineates the different study arms and their implications in the assessment of efficacy. The VISION (phase III) trial will provide data of critical value to the field of theranostics and especially the field of prostatic cancer management.
Prostate cancer is the most common cancer and the second most common cause of cancer-related death in men (1). Evolving diagnostic and therapeutic strategies for men with advanced-stage, metastatic, prostate cancer have revolutionized the field and are of major clinical and economic interest, with the potential to extend survival while maintaining quality of life. One such strategy involves the use of agents that combine diagnostic and therapeutic capabilities. These agents can identify the presence of a target on a patient’s cancer and normal tissues, to enhance the likelihood of patient benefit and minimize needless exposure or normal-organ toxicity. Some term the development of these agents theranostics.
NOTEWORTHY
PSMA-targeted ligands have significantly changed the management of prostate cancer patients.
The phase III VISION trial is needed to prove the benefit of this novel therapeutic according to current oncologic standards.
Failure of the VISION trial would be a drawback for the entire field of theranostics.
One molecular target of intense interest has been prostate-specific membrane antigen (PSMA), a transmembrane protein that was discovered over 25 years ago and has been the subject of intense investigation since (2–11). The ability to identify PSMA-expressing prostate cancer cells using a noninvasive imaging-based method, followed by administration of experimental therapy, has led to the development of 68Ga-PSMA-11, a diagnostic compound used to select patients for experimental treatment with 177Lu-PSMA-617 radioligand (3,12,13).
Developed by the German Cancer Center in Heidelberg, PSMA-617 labeled with 177Lu has garnered attention as an experimental therapeutic compound. In case reports and published patient series, it has shown promising response rates and low toxicity in men with advanced prostate cancer, and in the German Multicenter Study, it showed a prostate-specific antigen decline of 50% and an overall response rate of 45% (14–17).
An Australian phase II study led by Michael Hofman that treated 30 metastasized castration-resistant prostate cancer (mCRPC) patients who had significant prior treatment exposures resulted in significant declines in prostate-specific antigen with minimal toxicity (18). On the basis of these promising data, 68Ga-PSMA-11 and 177Lu-PSMA-617 are now being evaluated in a trial called VISION, an international prospective open-label, randomized phase III study in men with PSMA-expressing mCRPC (ClinicalTrials.gov identifier NCT03511664).
PHASE III VISION TRIAL
The overall design of the trial, and its primary and secondary endpoints, are depicted in Figure 1. Patients are randomized on a 2:1 basis to receive either the best standard of care (SOC) along with 177Lu-PSMA-617 or the best SOC alone.
Men with metastatic prostate cancer have access to an expanding armamentarium of life-prolonging agents that can be applied early in the clinical course of metastatic disease (e.g., docetaxel, enzalutamide, apalutamide, or abiraterone) or in the context of mCRPC. Indeed, men with mCRPC may have already received chemotherapy and yet still have an intact performance status, be candidates for further treatment, and be appropriate for clinical trials. In recognition of these numerous treatment options for mCRPC, including first- and second-generation androgen receptor axis–directed drugs, palliative maneuvers, and other SOCs, the VISION trial was designed knowing that there are many ways to care for the chemotherapy-exposed mCRPC treatment population. Because of safety concerns, chemotherapy and radium were not considered to be SOCs for this trial population, as the dosing and side effects of tumor-directed radiotherapy in combination with these marrow-toxic agents have not yet been defined. Patients who require or are likely to benefit from second-line chemotherapy are not allowed in the trial.
IMPORTANCE OF THE VISION TRIAL
The trial design contains a subtle, but critical, feature. Namely, it does not compare the SOC to treatment with 177Lu-PSMA-617. The design compares the SOC + 177Lu-PSMA-617 against the SOC. Thus, all therapeutic options, with the exception of cytotoxic, bone-targeted radiotherapy or other investigational treatments, can be used in either arm of the VISION trial. This leads to a critical issue. Patients who are in both arms of the trial must have expert care in the administration of systemic therapy for mCRPC and in the management of side effects of both the disease and the SOC systemic treatments, but this issue is especially relevant for patients in the control arm. For the trial to succeed, investigators must have a facile knowledge of SOC options available to the patients; the ability to manage end-stage prostate cancer patients using SOC options; and the ability to have a frank discussion with trial candidates regarding their expectations if assigned to the SOC-only arm. In addition, since many patients have seen data on the Internet suggesting that 177Lu-PSMA-617 can have an antitumor effect, investigators must impart a clear understanding that 177Lu-PSMA-617 has not, to date, shown any survival advantage or other metric of clinical benefit over the SOC.
This last point is especially important. The VISION trial is the first international, randomized study testing the hypothesis that overall survival is increased after treatment with 177Lu-PSMA-617 in men with advanced-stage prostate cancer. The trial also contains an alternate primary endpoint of radiographic progression-free survival whose integrity requires that patients assigned to the control arm continue receiving the SOC until such time as a clinical or radiographic progression-free survival event occurs. On the occurrence of such an event, these patients can then receive any and all options available to them, including other experimental therapy, but not 177Lu-PSMA-617. Maintaining control arm patients in the study until the point of a radiographic progression-free survival event correlates with the speed at which the trial reaches the alternate primary endpoint; the more intact the integrity of the study remains, the faster will arrive the answer of whether 177Lu-PSMA-617 fulfils its potential as a new therapeutic option.
If the VISION trial succeeds, it establishes a new line of therapy for prostate cancer that becomes the developmental paradigm for theranostics: the ability to use 68Ga-PSMA-617–based imaging to identify patients for treatment with 177Lu-PSMA-617. If successful, it may become impossible to conduct any subsequent study testing whether the VISION target population benefits from 177Lu-PSMA-617 in terms of overall survival. Alternatively, failure of the VISION trial—meaning that the largest well-designed and executed study of a theranostic pair has failed—would be a drawback for the entire field of theranostics. Independent of the activity of the drug, success or failure is in the hands of the clinical investigators and their ability to maintain the integrity of the VISION trial as it is designed.
DISCLOSURE
Kambiz Rahbar reports being a compensated consultant for ABX and has received consultant fees from Bayer and lectureship fees from Janssen Cielag, Amgen, AAA, and SIRTEX. Lisa Bodei is a consultant to AAA (compensation: hotel and dinner), Ipsen (noncompensated), and Curium (compensation: travel). Michael J. Morris is an uncompensated consultant for Astellas, Bayer, and Endocyte; is a compensated consultant for Advanced Accelerator Applications, Blue Earth Diagnostics, and Tokai; has institutional research contracts with Bayer, Sanofi, Endocyte, Progenics, Corcept, and Roche; and has received travel grants from Bayer, Endocyte, and Fujifilm. No other potential conflict of interest relevant to this article was reported.
Footnotes
Published online Aug. 26, 2019.
- © 2019 by the Society of Nuclear Medicine and Molecular Imaging.
REFERENCES
- Received for publication July 16, 2019.
- Accepted for publication August 19, 2019.