Trials / Recruiting

RecruitingNCT07293585

Vascular Optimized Radiotherapy Tuned to Critical Structures for Erectile Function Using High-Precision X-Ray Treatment

Summary

With people living longer after being treated for prostate cancer, quality of life has become a concern when considering the treatment plan. Sometimes after radiation therapy, patients may experience problems that affect the urinary and bowel systems, along with sexual function. Stereotactic body radiotherapy (SBRT) is a type of radiation technique that delivers five high doses of radiation. At University of California at Los Angeles (UCLA), we have the option to administer SBRT in both our CT-guided and MRI-guided radiation machines. This trial aims to determine the most effective method for protecting the nerves and blood vessels essential for erectile function, utilizing a technique known as neurovascular sparing. This technique uses images (i.e., MRI) to map the neurovascular bundles of nerves and blood vessels, which are crucial for erectile function. "Adapting" the radiotherapy treatment for each of these five treatment sessions could enable a more precise delivery of your radiation treatment that is customized based on your internal anatomy immediately before the treatment starts. This is also a standard and low-risk intervention used in many different types of cancer. However, it is a very labor-intensive and time-consuming procedure that requires a team of experts to work together before each of your radiotherapy sessions. We are unsure if the increased complexity associated with this adaptive treatment reduces side effects.

Detailed description

The mechanism implicated in sexual function decline following radiotherapy involves injury to vascular structures surrounding the prostate which are critical for normal erectile function, namely the corpora cavernosa, internal pudendal arteries, and neurovascular bundles. These structures are all in close proximity to the prostate gland and are often included at least partially within the planning target volume margin of treatment plans. As noted above, these planning target volume (PTV) expansions were historically large due to the need to ensure adequate coverage of the target volume to achieve disease control although this likely came at the cost of higher rates of treatment-related toxicity. With enhanced technology for target visualization and intra-fraction motion management, it is technically feasible to reduce margins and spare surrounding normal tissue from receiving the full prescription dose while still treating the target volume with high confidence. Beyond reducing the isometric PTV expansion due to increased precision in radiation delivery with modern techniques, however, it is now technically feasible to crop out these sensitive Organs-at-risk (OARs) from the final PTV volume in order to further spare them from receiving excess dose. This process, referred to as neurovascular-sparing (NV-sparing), involves the fusion of an MRI and/or MR angiogram to standard radiation planning images to allow accurate contouring of the internal pudendal arteries and neurovascular bundles so that these can be intentionally spared. Daily online adaptive replanning may also play a role in ensuring appropriate coverage of the target volume and sparing of OARs as intended by the treatment plan. To date, no investigations have reported on the clinical or dosimetric outcomes of patients treated with an NV approach in conjunction with these other methods. Furthermore, specific dose constraints for these structures are largely unknown due to the lack of empiric evidence to guide selection.

Conditions

• Prostate Cancer

Interventions

Timeline

Start date

2025-12-16

Primary completion

2035-12-16

Completion

2036-12-16

First posted

2025-12-19

Last updated

2025-12-19

Locations

1 site across 1 country: United States

Regulatory

• FDA-regulated device study

Source: ClinicalTrials.gov record NCT07293585. Inclusion in this directory is not an endorsement.