Clinical Trial Details
— Status: Active, not recruiting
Administrative data
| NCT number |
NCT04883281 |
| Other study ID # |
STU-2021-0401 |
| Secondary ID |
|
| Status |
Active, not recruiting |
| Phase |
Phase 2
|
| First received |
|
| Last updated |
|
| Start date |
February 23, 2022 |
| Est. completion date |
July 15, 2024 |
Study information
| Verified date |
January 2024 |
| Source |
University of Texas Southwestern Medical Center |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Varian Medical Systems has recently deployed a completely novel radiation treatment system
called EthosTM, a first-of-its-kind system that allows for daily adapative radiotherapy
(DART), such that the treatment for that day can be created on-the-fly based on the patient's
current positioning and anatomy. This system is commercially-available and FDA-approved, and
UTSW Radiation Oncology has installed two such units. The ability to adjust the dose delivery
every day means both that adaptive therapy is possible with every fraction and that the PTV
margin can be dramatically reduced/eliminated, since investigators are treating for that
day's patient setup. Investigators are therefore proposing a randomized trial using DART with
near marginless (ML) setup margins (a 1 mm margin will be retained for intrafractional
motion).
Description:
IMRT with daily cone-beam computed tomography (CBCT) set up is the current recommended
radiation technique for head and neck squamous cell carcinoma. The conformality of IMRT has
made it possible to reduce dose to normal tissues, but it also predisposes the treatments to
drastic delivered dose deviations due to changes in the patient (e.g. weight loss, muscle
atrophy, or normal tissue edema) or in the tumor (e.g. treatment response or treatment
related edema). These changes can create poor coverage and/or cold spots in the tumor and
increased coverage and/or hot spots in the normal organs at risk. Image guidance with CBCTs
can help reduce set up error between treatments, but image guidance can't adjust for these
patient or tumor changes.
Adaptive radiotherapy (ART) is the process of replanning the patient's radiation plan by
adjusting the target structures, organs at risk structures, and optimal radiation delivery
during the radiation therapy course. ART allows treating physicians to account for all the
patient or tumor changes that can't be currently resolved with image guidance. Previously,
ART was a prohibitively resource and time-consuming process that could only be performed once
or twice during a conventional 6.5 to 7-week head and neck radiation treatment course in
select patients with substantial structural changes. However, with the recent advent of
adaptive software, ART can now be performed on a daily basis.
The data on the possible advantages of ART in head and neck cancer is still limited to small,
mostly pre-clinical studies. In a feasibility study, five patients with locally advanced
HPV-positive oropharynx cancer undergoing definitive chemoradiation underwent an MRI every
two weeks during their treatment. The results showed an average decrease in the primary tumor
GTV volume of 44%, 90%, and 100% and an average decrease in the nodal GTV volume of 25%, 60%,
and 80% by at weeks 2, 4, and 6 weeks, respectively. Another similar study on eight patients
saw an average 70% GTV volume reduction by week 6.
In addition to tumor coverage, parotid glands are of particular interest in ART because of
their radiosensitivity and association with xerostomia and decreased quality of life.
Toxicity of salivary glands are related to dose as a continuous variable, so even modest
decreases in dose can have a clinical impact. The average volume of the parotids has been
reported to decrease as much as 14.7%, 37%, and 48% by the end of weeks 2, 4, and 7. The
parotid glands also appear to shift superiorly and medially during treatment. Feasibility ART
studies have shown that the dose to the parotid may decrease by as much as 5.5 Gy with ART.
Therefore ART holds the promise of preserving the expected dose distribution to salivary
OARs, improving long-term patient outcomes.
The ability to ensure coverage of the target structures and proper avoidance of organs at
risk on a daily basis also greatly improves the confidence of the daily set-up and targeting.
Current recommended radial PTV margins with daily CBCT are 3-5 mm, with even larger margins
recommended for patients at risk of larger inter-fraction variability. These PTV margins are
built to ensure the disease is not missed by the treatment due to daily setup error. However,
these margins also significantly increase the irradiated volume, since the volume increases
exponentially with each additional millimeter. Therefore, decreasing margins, even by a few
millimeters, can results in large changes in treatment volume and improvement in toxicity.
In a retrospective Danish analysis of patients treated with 5 mm versus 3 mm PTV margins,
Navran et al. noted that acute grade 3 toxicity (65% vs 53.8%, p = 0.008) and late grade 3
dysphagia (20.4% vs 11.1%, p = 0.012) were significantly lower in the smaller margin group.
There were no differences in disease outcomes between the two groups. In a retrospective
study analyzing the benefit of changing the margin on gross disease from 8 mm to 5 mm, just a
3 mm difference, Samuels et al. found that plans with the smaller PTV margin had a clinically
meaningful improvement in the normal tissue complication probability for the ipsilateral
parotid gland and contralateral submandibular gland when compared to conventional PTV margin
plans. In fact, 40% of patients would have theoretically experienced an improvement in the
function of both of these glands, just by modestly shrinking the PTV.
