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Daniel Spratt, MD, discusses the expanded role of radiation therapy for the treatment of patients with prostate cancer, delves into the optimal approach for using radiation in tandem with hormonal therapy for these patients, and highlights ongoing research focused on minimizing adverse effects associated with radiotherapy.
Notable advancements in radiation therapy have allowed for the continued reduction of toxicity and enhancement of tumor control through less invasive, more convenient options for patients with prostate cancer in a growing number of indications, according to Daniel Spratt, MD.
“It was exciting to share the advances in radiation oncology for patients with genitourinary [GU] cancers. We covered the evolution of radiation therapy, from what it used to be in the 1980s, all the way to now in 2023 and beyond, [where we have seen] the transformative role of this technology,” said Spratt, who presented on updates in radiation oncology at the 2023 LUGPA Annual Meeting.1
In an interview with OncLive®, Spratt discussed the expanded role of radiation therapy for the treatment of patients with prostate cancer, delved into the optimal approach for using radiation in tandem with hormonal therapy for these patients, and highlighted ongoing research focused on minimizing adverse effects (AEs) associated with radiotherapy. Spratt is the chairman and professor of Radiation Oncology at University Hospitals Seidman Cancer Center and Case Western Reserve University in Cleveland, Ohio.
Spratt: In the 1980s, we saw fairly high toxicity, high inconvenience, and low tumor control [with radiation therapy]. Now, we’re talking about less than 1% of men with prostate cancer getting modern radiation therapy with image guidance and SBRT to give treatment in just 5 treatments. We are experiencing unprecedented, limited toxicity, as well as other advances with different types of technology, [such as] rectal spacing devices and other types of improved imaging. Ongoing trials are even further aiming to reduce AEs, whether they are gastrointestinal AEs, GU AEs, and even sexual AEs—trials are ongoing with a novel technique called vessel sparing radiation. [These advances] have been exciting for patients with prostate cancer.
There's a wide array of other advances with radiation therapy in terms of the indications. We're seeing [the use of radiation] not just in patients with localized or recurrent prostate cancer after surgery; we now have randomized data to show benefit in patients with metastatic disease or oligometastatic disease, and there have even been recent data in advanced metastatic castration-resistant prostate cancer. Never before has radiation played such an integral role in the [treatment] of men with prostate cancer.
It's been fantastic to see the evolution in systemic therapies, such as targeted therapies and immunotherapies. [However], these haven’t decreased the role of radiation therapy other than in some hematologic malignancies. In solid tumors, if anything, the role of radiation has expanded.
One reason [the role of radiation has expanded] is the accuracy and precision of treatment, irrespective of a patient’s mutational profile. Radiation, irrespective of that heterogeneity and those mutations, has a high probability of killing those cancer cells.
Another reason for the expanded use of radiation is that with these targeted therapies or immunotherapy, sometimes patients experience oligo-progression. There's some site that is progressing, but the therapy is keeping the rest of the metastatic disease under control. Therefore, radiation is a nice, non-invasive, and now very convenient and accurate way to get rid of those resistant clones.
I would view [radiation and systemic therapy] as complementary. Together, we're seeing unprecedented long-term survival rates in men with metastatic [prostate cancer] with more effective systemic therapy and local therapy.
For a long time, dating back to the 1970s, there was some signal that there was a synergistic action between radiation and hormone therapy, androgen deprivation therapy [ADT], or AR signaling inhibition. That has been borne out now over numerous trials over the past decades.
We've done work to try to understand how to optimally give [hormone therapy and radiation] together. Historically, people thought giving hormone therapy before radiation somehow might reduce hypoxia or reduce other things that were thought to be driving radiotherapy resistance. What modern work has shown is that [this is probably not the case], and it probably is not having an oncologic benefit. [Hormone therapy] is going to put the cancer to sleep, but it's probably not optimally helping the radiation. We've now learned that by giving hormone therapy right after radiation, it inhibits the repair of DNA damage. Giving the radiation together with hormone therapy and continuing it seems to elicit the greatest synergistic benefit.
With radioligand therapy—some people call it radiopharmaceutical therapy—there are many different agents that are in development right now. The exciting aspect of it and why I think radioligands have shown [promise] in prostate cancer over another efficacious treatment such as antibody-drug conjugates [ADCs] is that radiation sometimes is cancer agnostic. Both [ADCs and radioligands] are trying to deliver a drug or deliver radiation systemically, based on its homing or targeting approach. [Radiation delivered via radioligands] can be highly effective, and they have what we call a pathlength. Depending on the type of radiation used, such as a beta emitter or an alpha emitter, it can potentially hit multiple cancer cells. It doesn't have to immediately be targeted to 1 cell.
All treatments have potential AEs, and it’s important that patients know that. However, things are being actively worked on right now for patients with localized prostate cancer. High-grade AEs are now pretty uncommon, but how do we eliminate the moderate or mild AEs that still can affect quality of life?
Strategies being evaluated include a concept called dose painting, where we can effectively give higher doses to the part of the prostate to where the dominant nodule is, and potentially give lower doses than we normally would to the remainder of the prostate. [This strategy] is actively undergoing trials right now to see if we can limit urination AEs and any of the lower-grade bowel AEs, and we are anticipating those results in the upcoming years.
The latest trial [on SBRT] called the phase 3 PACE-B study [NCT01584258] from the United Kingdom had [5-year] results presented at the 2023 ASTRO Meeting, [where study authors concluded that SBRT should be considered a new standard of care for patients with low- and favorable intermediate–risk prostate cancer].2
With radiation therapy, approximately 12% of men will report new erectile dysfunction 2 years after radiation. That's far better than most other treatments, such as surgery, which cause higher rates of erectile dysfunction. However, 12% [is still significant]. We are working on techniques and testing them to see if we can improve erectile function preservation in these patients, given its impact on quality of life.
There are some great advances in kidney cancer. Historically, radiation actually played almost no role [in kidney cancer], and the mantra was that it was believed to be radio-resistant. As we have learned over the last 20 years, using ablative radiation with SBRT and higher doses per treatment is very efficacious.
Trials have been reported this past year of treating patients with metastatic kidney cancer to delay or avoid them going on to systemic therapy, and this has been a very effective approach. Ongoing trials are looking at giving radiation to the kidney itself, where the primary tumor is metastatic; this is similar to a cytoreductive nephrectomy approach, but with SBRT. That is a trial called the phase 2 SAMURAI study [NCT05327686].
Even in patients with newly diagnosed, localized kidney cancer, a lot of work has been done in trials that have been reported. Now with longer-term outcomes, we're talking about approximate 95% to 98%, local control with SBRT, where you don't have to take the kidney out and [patients] don't need surgery. Therefore, [the use of radiation in patients with kidney cancer] is definitely growing in acceptance as more of these data come out.
We are able to personalize treatment for patients and maximize quality of life. The way that's being done with radiation therapy is convenient. For example, treatments have gone from 8 [treatments] down to 5 treatments, and some ongoing trials are going down to 2 treatments. These treatments are outpatient and non-invasive. These improvements do affect people, especially if they have loved ones, their caregivers, or they're working.
Additionally, the accuracy of that radiation [is beneficial] not only in planning, but in its delivery to make sure we're putting the radiation dose where it matters most.
Finally, we often give hormone therapy with radiation for various indications [in prostate cancer], and we have new tests, whether it's prognostic tests like Decipher or predictive tests like ArteraAI that can better personalize the use of hormone therapy with radiation to maximize tumor control and minimize AEs to improve quality of life.