Thursday, December 19, 2019

Beyond PSMA - FAPI theranostics

(frequently updated)

Ideally, a new diagnostic and therapy ("theranostic") will have the following qualities:
  • it will be theranostic for all cancer (high sensitivity)
  • it will not be theranostic of anything that isn't cancer (high specificity)
In my previous article (see this link), we saw how PSMA heterogeneity can lead to treatment failure. PSMA is pretty specific, except for the salivary glands, the kidneys, and a few other places where expression is low. There is an opportunity to create ligands that are more sensitive and more specific.

Cancer is a tissue-based disease too

We often think of cancer as a cell-based disease: some rogue cells go wild, become immortal, and replicate out of control (see "The Hallmarks of Cancer"). In 1889, Stephen Paget put forth the "seed and soil" hypothesis: the cancer (the seed) thrives in "congenial soil." Not only does the seed find such soil, we have since learned that it actively creates its soil. This led to a new understanding of cancer as a tissue-based disease (see this link). What we call the "microenvironment" of the cancer is not just a passive player supporting the cancer cells; it actively sends signals to some cells (via extracellular vesicles - small "bubbles" containing microRNAs, enzymes, and essential proto-oncogenes) that cause them to become cancerous, and other cells to become supportive tissue - collagen, fat, blood vessels and nerves (collectively called stroma). They also suppress immune infiltration, attract regulatory T cells and certain kinds of macrophages that prevent immune response, and release cytokines that may cause or suppress inflammatory  response. The "reactive stroma" allows the tumor to grow and expand. This starts a positive feedback loop that enables the tumor (a collection of cancer cells and their stroma) to grow relentlessly.

Cancer-Associated Fibroblasts (CAF)

Fibroblasts are the most common cells in our connective tissue, which is the most prevalent tissue in our bodies. They create the collagen, fibronectin, the ground substance, adipose tissue, cytokines, growth factors, and other proteins that makes up the extracellular matrix that supports tissue architecture. When one cuts one's fingers, fibroblasts are activated and create the structure needed for the wound to heal. Fibroblasts are involved in cell adhesion, growth, migration and differentiation. Because they give rise to many different kinds of cell-precursers and proteins, they may be thought of as stem-cell-like (mesenchymal). The interested reader may wish to read this.

When cancer cells in the prostate go awry, they may, at some point go from being normal epithelial cells to being mesenchymal cells (called the epithelial-to-mesenchymal transition or EMT). EMT cells are capable of traveling outside of the prostate, where they can grow and clump into metastatic tumors, replete with cancer-associated fibroblasts (CAFs). The tumor can be thought of as a wound that doesn't finish healing and continually creates more wounds. In some cancers, 90% of the tumor volume is the stroma.

The tumor stroma can impair drug deliver, participate in drug resistance, and change the very nature of the cancer within (its phenotype). The stroma is where immunological agents and vascular-targeted agents have their effect (or lack of effect in the case of prostate cancer). See this link for a detailed discussion. It is also potentially targetable if it has a specific characteristic protein.

Fibroblast Activating Protein Inhibitor (FAPI)

There are several characteristic proteins in CAFs. One called Fibroblast Activating Protein (FAP) seems to be particularly useful. It is highly specific - it has only been found in cancers of epithelial origin (like prostate cancer), and never in healthy tissue. Immunohistochemical analysis of tumors has demonstrated a strong correlation between high FAP expression and worse prognosis. It has also been found in damaged tissue: inflamed tissues as in rheumatoid arthritis, myocardial infarction, liver cirrhosis, and atherosclerosis.

Uwe Haberkorn and researchers at the University of Heidelberg have synthesized a FAP inhibitor (FAPI) that seems to inhibit production of CAFs specifically and thoroughly.  Not only does it inhibit progression in mouse models, but it seems to "fix" the problems associated with the cancer stromal compartment - imperviousness to immunotherapies and angiogenesis inhibitors. They are fine-tuning the ligand to be more sensitive and specific, and to last long enough in clinical use for theranostic applications.

Kratochwil et al. reported on the Ga-68-FAPI uptake in 28 different tumor types in 80 patients, in whom FDG, PSMA or other PET scans failed to detect much cancer. Good uptake was seen for almost all solid tumors. Above average uptake was seen for sarcoma, salivary, esophageal, cholangiocellular carcinoma, breast, lung, prostate, pancreatic, thymus, head and neck, ovarian, desmoid, chordoma, and colorectal cancer.

Lindner et al. reported on two metastatic breast cancer patients treated with Y-90-FAPI-04 as a proof of concept. They both reported an immediate reduction in pain. Dr. Baum at Bad Berka has treated 10 patients with a single low dose of Lu-177-FAP-2286. It accumulated in tumors, and had no associated toxicity. There was some symptomatic relief in some patients, and he plans to give them a second injection.

It is also possible to target fibroblast growth factors using inhibitors rather than radioactive agents, as described in this article.

Recently, we saw how two PET indicators were more sensitive than one. In that study, a GRPR-targeted ligand was paired in the same molecule with an integrin-targeted ligand. Integrins are created downstream from fibroblasts. GRPR is found in prostate cancer cells but is also highly expressed in gastrointestinal and CNS tissues. This limits its usefulness as a therapeutic target. However, the concept of double therapeutic targets is potentially useful for prostate cancer, where both PSMA and FAPI may be targeted.

Clinical Trials

In the US, preliminary clinical trials of FAPI-targeted PET indicators have begun.


So far, there are no therapeutic trials of Lu-177-FAPI that I am aware of, although the Haberkorn group may well be doing exploratory work. Big Pharma has taken notice; Lantheus, Novartis, Clovis, and Avacta have announced investments.

There is also a fibroblast inhibitor, erdafitinib, being explored in clinical trials:









Sunday, December 15, 2019

Why Lutetium-177-PSMA treatment sometimes may not help, and may even harm

(updated)

Lu-177-PSMA usually improves survival

We've seen in a couple of small trials in Germany and Australia that Lu-177-PSMA seemed to provide better than expected survival. In Germany, median overall survival was 12.9 months across 104 patients. In Australia, median overall survival was 13.3 months across 50 treated patients. In both trials, all or almost all patients had already received taxane chemotherapy and either enzalutamide or abiraterone. There was no control group in either trial, so we can only guess at what overall survival would have been without the therapy.

In the "ALSYMPCA" trial of Xofigo, among the subgroup of patients who had received docetaxel for their painful mCRPC (see this link),  median overall survival was 14.4 months with Xofigo vs. 11.3 months with placebo. The ALSYMPCA trial was conducted before abiraterone and enzalutamide were approved, so it is impossible to know how prior treatment with one of those might have changed survival.

In a recent trial of Jevtana as a third-line therapy, after docetaxel and either abiraterone or enzalutamide, median overall survival was 13.6 months for Jevtana vs. 11.6 months for the other second-line hormonal. 

So, in heavily pre-treated patients, Lu-177-PSMA seems to improve survival about as well as Xofigo or Jevtana when used as a third-line therapy. The VISION trial  found that LuPSMA treatment increases survival by 5 months in heavily treated patients (similar to Xofigo).

PSA is not always a good indicator of effectiveness, as has been found for Xofigo and Provenge. Lu-177-PSMA reduced PSA in about 2/3 of treated patients in most studies. That leaves about 1/3 of patients who derived no benefit (even though they had PSMA-avid tumors), and waterfall plots showed that a few patients had large increases in PSA following PSMA-targeted therapy.

It is worth noting that the PSMA protein contributes to the survival of the cancer, and just the PSMA ligand that attaches to it has some activity in delaying progression, even without a radioactive component (similar to the way an anti-androgen attaches to the androgen receptor, delaying progression). It is also worth noting that ADT initially increases PSMA expression, but decreases its expression with continued use.

The opportunities are:
  • to select patients who are likely to benefit
  • give alternative therapies (like Jevtana) to patients who are unlikely to benefit
  • provide adjuvant therapies that may increase survival

PSMA avidity - optimal point in time

It has long been known that PSMA is a moving target. The advent of PSMA PET scans has enabled us to track PSMA expression. Cancers that express a lot of PSMA (called PSMA-avid tumors) can be distinguished from cancers that express very little. Radiologists determine avidity by comparing the uptake of the tracer in cells that express PSMA to the uptake of the tracer in cells known to not express PSMA. Early low-grade prostate cancer does not express PSMA at all. Higher grade prostate cancer may express some PSMA. PSMA expression really starts to take off when the cancer metastasizes, although it is highly variable between patients. About 90-95% of metastatic men express at least some PSMA on their prostate cancer cells. At some point, however, as genomic breakdown continues, PSMA is no longer expressed by metastases. Treating when PSMA is not adequately expressed can cause a lot of toxicity to healthy tissues (especially kidneys and salivary glands) and little therapy (see this link and this one). Thus, there is an optimal point for treating each patient with PSMA-targeted therapy. Treatment too early or too late, may exert selective pressure on the predominant non-PSMA-types, allowing them to take over.

Michael Hofman and others at the Peter MacCallum Cancer Center in Melbourne (see this presentation and this link) have initiated several clinical trials using Lu-177-PSMA at earlier stages of disease progression:

  • #lutectomy trial (Declan Murphy,  PI) is treating PSMA-avid high-risk patients with Lu-177-PSMA, followed by prostatectomy and pelvic lymph node dissection
  • #upfrontPSMA (Arun Asad, PI) is treating patients first diagnosed with high volume metastases with Lu-177-PSMA + ADT + docetaxel vs ADT + docetaxel.

Other opportunities for early use include Lu-177-PSMA treatment for those in the following settings:
  • active surveillance
  • persistent PSA after prostatectomy
  • salvage treatment after first recurrence
  • salvage treatment after second recurrence
  • metastatic CRPC before docetaxel or advanced hormonal therapies
  • non-metastastic (on bone scan/CT) CRPC before docetaxel or advanced hormonal therapies

Centers in Germany may be willing to treat patients per protocol (i.e., outside of a clinical trial) in some of those situations.

Repopulation

In radiobiology, one of the ways in which radiation can fail to destroy cancer is called repopulation. It means that when radiation kills some cancer cells but leaves many behind, the remaining ones now have access to space in which to expand and access to nutrients and oxygen that the other cancer cells had deprived them of. Paradoxically, the tumor can then grow faster than it ever would have before the treatment. This is sometimes seen with rapidly growing tumors, as some head and neck cancers. They sometimes irradiate those cancers multiple times a day to prevent repopulation.

Repopulation is never seen with X-ray (or proton) treatment of relatively slow-growing prostate cancers. X-rays penetrate throughout the prostate and kill all the cancer there. If there is any survival of an oxygen-deprived tumor core, it will be killed by the next fraction of X-rays in a day or two. However, Lu-177 emits beta rays that may only penetrate to about 125 cells around each target. Ac-225 (also sometimes used in PSMA therapy) only kills about 8 cells around each target. With such short-range killing, there is a real danger of repopulation if there are insufficient PSMA targets within the tumor. Multiple treatments are usually not given for several weeks, and the tumors may have changed by then.

PSMA heterogeneity

What we have learned recently is that not only does PSMA expression change over time, but in a given patient, some tumors may express PSMA and some may not. Moreover, even within a single tumor, some cells may express PSMA and some may not.

Paschalis et al. looked at the degree of PSMA expression of 60 patients with metastatic castration-resistant prostate cancer (mCRPC). They also looked at tissue samples of 38 of them taken when they were diagnosed with hormone-sensitive prostate cancer (HSPC). To detect the amount of PSMA expressed, they used an antibody stain that attaches to the part of the PSMA protein that lies above the cellular membrane. They rated the tumors "0" if there was no PSMA up to "300" if all cells expressed PSMA. They also performed a genomic analysis, looking for mutations in over 100 genes associated with DNA-repair defects.

Among the tumor samples from men with HSPC they found:
  • 42% of the 38 men with HSPC  had no PSMA at diagnosis - it only emerged later
  • 5 of the 6 HSPC men diagnosed with Gleason score 6 or 7 had little or no PSMA expression at that time
  • About half of 30 HSPC men diagnosed with Gleason score 8-10 had little or no PSMA expression at that time
  • Those who expressed PSMA had a worse prognosis
  • Expression of PSMA varied greatly (heterogeneous) between patients
  • Expression of PSMA varied greatly between biopsy samples from the same patient
  • The higher the PSMA expression in a patient, the greater the amount of PSMA heterogeneity
Among the tumor samples from the 60 men with mCRPC they found:
  • PSMA expression had increased from when they were diagnosed with HSPC
  • Half of the tumors with no PSMA at HSPC diagnosis continued to have no PSMA
  • 73% expressed PSMA; 27% did not - only 1 of whom had neuroendocrine prostate cancer
  • 84% of those expressing PSMA exhibited marked PSMA heterogeneity
  • Heterogeneous patterns were identified:
    • PSMA positive and negative cells interspersed in a single area
    • PSMA-positive islands in a sea of PSMA-negative cells
    • PSMA-positive regions separated by >2 mm from PSMA-negative regions
    • Some metastases wholly PSMA-positive, some wholly PSMA-negative in the same patient
  • Bone and lymph node metastases had similar PSMA expression; liver metastases (none neuroendocrine) had lower PSMA expression
Analysis of DNA-repair defects revealed:

  • mCRPC patients with DNA-repair defects had higher PSMA expression
  • HSPC patients without DNA-repair defects were less likely to become PSMA-positive
  • Patients treated with PARP inhibitors were more likely to respond if they were PSMA-positive
  • For validation, in a separate sample of tumors, those with DNA-repair defects were found to have much higher PSMA expression than those without such defects. This was especially true for somatic mutations in BRCA2, ATM, and dMMR.
  • PSMA was downregulated in androgen-independent basal cancer cells (resistant to advanced anti-androgens) and neuroendocrine cells.

The significance of this study is that it may explain why about a third of PSMA-avid patients do not respond to Lu-177-PSMA therapy. The emitted beta particles may kill cells within about 125 cells from where they are attached at the PSMA site. Thus cells that do not express PSMA that are more than 2 mm from a PSMA-avid site will not be killed (see "Repopulation" above).

The authors hypothesize that DNA-damage repair defects cause PSMA to proliferate. If they are right, a PARP inhibitor (like olaparib), which has also been found to be effective when there are DNA-repair defects (see this link), may be able to increase the efficacy of PSMA treatment. This is the subject of an ongoing clinical trial.

(update 2/24/23) Sayar et al. report the results of a PSMA autopsy study.
  • 25% had no detectable PSMA
  • 44% had heterogeneous PSMA expression in multiple metastases
  • 63% had at least one PSMA-negative metastasis
  • Loss of PSMA expression was linked to epigenetic changes on the FOLH1 gene
  • Treatment of cells (in vivo and in vitro) with HDAC inhibitors restored PSMA expression
HDAC inhibitors are available off-label and include: Valproic Acid (Depakote), Zolinza (vorinostat), Beleotaq (belinostat), Faridak (panobinostat), and Buphenyl (phenylbutyrate).

Practical detection of heterogeneity/ clinical trials

Now that we know that heterogeneity can impact Lu-177-PSMA effectiveness, it behooves us to find a way of determining the degree of heterogeneity without doing a biopsy of every single metastatic site. One way is to give each patient two PET scans, so they could see the sites that exhibited PSMA expression as well as the sites that exhibited high uptake on an FDG PET scan.

It is futile to offer PSMA-targeted therapy if there are many sites that show up only on an FDG PET scan but few sites that display uptake of PSMA. It also may be futile to treat patients that show some sites where PSMA and FDG sites do not overlap - "discordant." On the other hand, where there is a high degree of overlap between FDG and PSMA - "concordant" - the PSMA radiotherapy will kill both cancers simultaneously. Of course, the ideal candidate would display only highly PSMA-avid sites.  Thang et al. reported on the survival of 30 patients who were treated with Lu-177-PSMA (who were either high PSMA/low FDG or concordant, compared to 16 patients who were excluded based on lack of PSMA (8 patients) or a high degree of discordant sites (8 patients). All patients were heavily pretreated.

  • Treated patients survived 13.3 months (median)
  • Untreated patients survived 2.5 months (median)
(update 12/2020) Michalski et al. looked at 54 patients. Some had at least one tumor that was positive on FDG, but negative on PSMA (FDG+/ PSMA-). They compared outcomes to patients that had only PSMA+ tumors. They found:
  • A third of patients had at least one FDG+/PSMA- tumor
  • Overall survival was FDG+/PSMA- patients was 6 months
  • Overall survival for PSMA+only patients was 16 months
(update 2/16/22) A secondary analysis of the TheraP trial of Jevtana vs LuPSMA looked at patient response depending on whether their cancer showed up also on FDG PET scans. They looked at the percent of men whose PSA reduced by 50% or more (PSA50) in the cohort that received cabazitaxel vs the cohort that received Lu177PSMA. Each cohort was analyzed according to whether they were highly avid on a PSMA PET scan (SUVmean≥10) "high PSMA" and whether their metabolic tumor volume on an FDG scan was greater than 200ml (MTV≥200) "high FDG". They required high PSMA (SUVmax≥20), and excluded men who were FDG+ and PSMA-.

  • In men with high PSMA, the PSA50 was 91% for Lu177PSMA vs 47% for cabazitaxel
    • Among men with high PSMA, the odds ratio of responding to Lu177PSMA was 12.2 vs 2.2 for cabazitaxel 
  • In men with low PSMA, the PSA50 was 52% for Lu177PSMA vs 32% for cabazitaxel
  • In men with high FDG, the PSA50 was 57% for Lu177PSMA vs 20% for cabazitaxel
    • Among men with a high FDG, the odds ratio of any response to either treatment was 0.44
  • In men with low FDG, the PSA50 was 70% for Lu177PSMA vs 44% for cabazitaxel

It is unknown whether the survival of untreated patients might be longer or shorter had they received treatment. It is possible that discordant patients may benefit from sequenced (before or after) or concomitant treatment with:
It is possible that such adjuvant treatment may decrease the population of discordant sites, and minimize repopulation effects.

Based on this new knowledge, it is recommended that patients who are good candidates for Lu-177-PSMA therapy have both a PSMA PET/CT scan and an FDG PET/CT at around the same time. FDG PET scans are generally covered by insurance; PSMA PET scans are not covered by insurance yet.

Saturday, December 7, 2019

Optimal chemohormonal sequencing for mCRPC MAY be Taxotere->Zytiga->Pluvicto/Jevtana/Xtandi with chemo

(1) Taxotere (docetaxel) first

In a retrospective study presented at the Society for Urologic Oncology meeting,  researchers at the Mayo Clinic reported on 112 patients with metastatic castration-resistant prostate cancer (mCRPC).

  • Group A (80 men) had docetaxel (Taxotere) followed by one of the second-line hormonal therapies: either abiraterone (Zytiga) or enzalutamide (Xtandi)
  • Group B (32 men) had a second-line hormonal therapy followed by Taxotere.
  • Bone metastases were more common in Group B (87%) than Group A (58%)

Three-year survival was:

  • cancer-specific survival: 87% Group A vs 64% Group B
  • overall survival: 82% Group A vs 61% Group B
  • results were similar for men with high volume metastases, excluding those with lymph node-only
This was not a prospective randomized clinical trial. It reaches a different conclusion from a couple of earlier retrospective analyses.  Sonpavde et al.  reported an analysis of 1445 patients at VA hospitals. They found no difference in overall survival among those who started with taxanes vs. those that started with a second-line hormonal therapy. In a study at Johns Hopkins, Maughan et al. reported that there were no statistically significant differences in total progression-free survival related to the order in which the medicines (Taxotere or Zytiga) were given. Both studies adjusted for disease characteristics.

In the STAMPEDE trial of newly diagnosed men with metastatic hormone-sensitive prostate cancer (mHSPC), there was no difference in survival among men who were randomized to get Taxotere or Zytiga first (see this link). The difference in the Mayo study may be due to "selection bias" in the retrospective study - Group A may have received Taxotere first because they were healthier, and more likely to survive.

But even if the survival difference is an artifact of the study methodology, there are other reasons to do Taxotere first:
  • Side effects are less when chemo is given earlier
  • In fact, side effects are no worse for chemo or Zytiga (see this link). The differences are in the kinds of side effects, but not in their seriousness.
  • By starting with 6 infusions of Taxotere, one is able to use Zytiga after only 15 weeks; but if one starts with Zytiga, it may be 3 years before Taxotere can be tried (see this link).
There doesn't seem to be any cross-resistance between taxanes and Zytiga (as there is between Zytiga and Xtandi). A pilot trial combined the two without finding excessive toxicity, and larger trials of the combination are ongoing; for example, this one. However, a randomized trial of docetaxel+Xtandi vs docetaxel alone found there was no survival advantage to combining them, but toxicity was higher with the combination.

(2) Zytiga (abiraterone) before Xtandi (enzalutamide)

Khalaf et al reported the results of a randomized Phase 2 trial in British Columbia. 202 newly diagnosed mCRPC men were randomized to either Zytiga or Xtandi first. After progressing on the first therapy, they were given the second therapy (cross-over).
  • The Zytiga-first men progressed after 19 months vs 15 months in the Xtandi-first group
  • After cross-over, PSA was reduced by more than 30% in 36% of those who had Xtandi-second vs only in 4% of those who had Zytiga-second
Until we have a larger study that follows men for the rest of their lives, we can assume that the extended progression-free time among those who use Zytiga before Xtandi will translate to extended survival.

It's worth noting that it has been found that Zytiga can work a median of 10 months longer if one switches from prednisone (10 mg/day) to dexamethasone (0.5 mg/day) when progression begins (see this link).

A trial combining Zytiga and Xtandi (+ADT) found there was no benefit to combining the two drugs, but toxicity was worse than Xtandi (+ADT) alone. A small trial of Zytiga monotherapy (without ADT) showed that it can reduce testosterone on its own and another small trial suggested that oncological outcomes were not compromised by the monotherapy.

(Update 2/9/21) A trial combining Zytiga and Erleada (+ADT) found there was a benefit in radiographic progression-free survival (rPFS) to combining the two drugs. rPFS was extended 6 months (from 17 mos. to 23 mos.) by the combination compared to Zytiga (+ADT) alone. With median follow-up of 55 months, there was no significant difference in overall survival. Unlike Xtandi, Erleada reduces androgen receptor expression.

(Update  2/21/21) Tagawa et al. reported that in a retrospective analysis of chemo-naive patients treated at the VA, Xtandi-first patients had a 16% reduced risk of death vs Zytiga-first patients - 1.4 months longer. But if they later switched to the other drug, their overall survival was the same. There was also no difference in survival if they later had chemo.

(3) Jevtana (cabazitaxel) or Pluvicto third.

Jevtana is currently FDA-approved for men in whom Taxotere has already been tried and failed. Jevtana and Taxotere (both taxanes) have been found to be virtually identical in oncological results when given as first-line therapy (see this link) with a similar degree of toxicity. If Taxotere and one of the second-line hormonal therapies (Zytiga or Xtandi) have already been tried, is it better to try the other second-line hormonal therapy next or is Jevtana a better choice for the third therapy? De Wit et al. found the answer in the CARD randomized clinical trial..

They randomized patients who already had Taxotere and one of the two second-line hormonal to receive either the other second-line hormonal or Jevtana.
  • 126 received Jevtana
  • 58 received Zytiga
  • 66 received Xtandi
After 9.2 months median follow-up, 
  • Imaging-based progression-free survival was 8.0 months for Jevtana vs 3.7 months for the hormonal therapy
  • The advantage for Jevtana was maintained regardless of risk characteristics and treatment history
  • The advantage for Jevtana was true regardless of which hormonal therapy it was compared to.
  • Overall survival was 13.6 months for Jevtana vs 11.0 months for hormonals.
  • PSA was reduced by at least 50% in 36% of men using Jevtana vs 14% using hormonals.
  • Tumors shrank in 37% of men using Jevtana vs 12% using hormonals
  • Serious adverse events of any grade were similar for all therapies at 39%.
  • Adverse events leading to death were more frequent with the hormonals (11%) than Jevtana (6%)
  • Pain was improved more by Jevtana (in 45% of men) than by hormonals (in 19% of men)
  • Skeletal events (fractures, spinal compression) occurred more frequently among those taking hormonals (51%) than Jevtana (29%)

Jevtana was at least as good or had a clear advantage on every measure of success.

(Update 9/16/20) Fizazi et al. reported the Quality of Life (QOL) outcomes of the CARD trial (above).
  • Pain response was better with Jevtana  than hormonals (46% vs 19%)
  • Time to pain progression was about twice as long with Jevtana (hazard ratio (HR)= 0.55)
  • Time to next symptomatic skeletal event was similarly longer with Jevtana (HR= 0.59)
  • Function scores and time to deterioration of function scores (e.g., ability to self-care, perform usual activities, mobility, mental status, sense of well-being, social/family well-being) were better with Jevtana



(4) Xtandi + chemo fourth

There is some evidence that taxanes (like Taxotere or Jevtana) can reverse one mode of hormonal resistance (AR-V7 splice variance). More evidence proved that Taxotere combined with Xtandi can extend its effectiveness even after it fails. Research continues on methods to reverse resistance (e.g., see subsection - "what's next?"). Although there is known cross-resistance between Zytiga and Xtandi, Xtandi usually works at least for a while after Zytiga.

Other medicines

Other medicines approved for men with mCRPC include older anti-androgens (like bicalutamide), Xofigo, Provenge, and Keytruda (but only in the rare event of MSI-hi/dMMR). It would save time if any of these could safely be piggybacked on top of another therapy.

Older anti-androgens (like Casodex or flutamide) are still used sometimes in the mCRPC setting, mostly in combination with a GnRH agonist (like Lupron). The combination is somewhat more beneficial (see this link) than a GnRH agonist alone, and provides a short-term benefit at low cost. Sometimes, the cancer learns how to feed on the anti-androgen, and removing it leads to a reduction in PSA (called antiandrogen withdrawal syndrome). However, because there is often cross-resistance, resistance to Casodex may encourage resistance to the stronger second-line hormonal agents (although there is no proof of this). Newer antiandrogens don't seem to create a withdrawal syndrome as much, although it has been observed in a minority of patients for abiraterone and enzalutamide.

It is unknown where the newest antiandrogens fit into sequencing. Erleada and Nubeqa have been approved for other indications, but not yet for mCRPC. Others (like proxalutamide) haven't yet cleared the first hurdle.

Xofigo cannot be prescribed after any visceral metastases have been detected, although it may work well on the bone metastases nevertheless. It works better sooner rather than later, but a trial combining it with Zytiga was stopped early because of a high rate of skeletal events. Early results of a new trial combining Xofigo and Xtandi show that adding a bone-protective agent (Xgeva or Zometa)  can ameliorate the problem.

Provenge may synergize with radiotherapies or chemo because they present many cancer antigens for the amped up immune system to tune into. There is some evidence to suggest that it synergizes with Xofigo. There is evidence that an abscopal effect (systemic immune response) may be augmented. Other immunotherapies, which show little therapeutic promise alone, may be beneficial in combination with chemo or other therapies.

PARP inhibitors are in clinical trials, and seem to be especially effective when there are BRCA1/2 mutations (germline or somatic). Several clinical trials are combing carboplatin with taxanes. Transdermal estrogen is inexpensive and is available now. Optimal sequencing or combinations are yet to be determined. 

Lu-177-PSMA-617 ("Pluvicto") and similar radiopharmaceuticals are in ongoing trials. (Update: see this link.) The TheraP trial proved that Pluvicto is equivalent in terms of overall survival as a third treatment compared to Jevtana. The VISION trial used it only among men who had been pre-treated with chemo and Zytiga or Xtandi. The FDA approval limited it to use after those other treatments. However, trials are ongoing for earlier use and in combination therapy. There is probably an optimum time for use of PSMA-directed therapies. Combination with different PSMA-targeted radionuclides (like Ac-225), and with multiple membrane targets are being explored.

There are myriad other potential therapies in clinical trials. Many are pathway growth inhibitors that may work best in combinations. Therapies tailored to specific genomic mutations are in their infancy.