Clinical Trial Details
— Status: Withdrawn
Administrative data
| NCT number |
NCT03215355 |
| Other study ID # |
NSHAREB#4793 |
| Secondary ID |
|
| Status |
Withdrawn |
| Phase |
Phase 4
|
| First received |
|
| Last updated |
|
| Start date |
August 2017 |
| Est. completion date |
August 2018 |
Study information
| Verified date |
January 2021 |
| Source |
Nova Scotia Health Authority |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
This is a feasibility study requiring only three patients to serve as a proof of concept that
gadoxetate disodium (a liver specific contrast agent) can be used to improve images taken
just before liver SBRT treatments.
The hypothesis of this research is that if gadoxetate disodium improves image quality at the
time of treatment, then it can be used for image guided radiotherapy (IGRT). Image guidance
is the procedure where the 3D CT image that is used to plan a radiotherapy treatment, is
aligned to a 3D image taken just before treatment. The better the alignment, the more
accurate the treatment, which is crucial for high dose treatments such as SBRT.
This research is important for two main reasons. First, it is much less invasive than the
standard of care which involves surgically implanting markers in the liver that can move over
time. The benefit to harm ratio for surgery, compared to an injection, is much more dramatic.
Furthermore, not all patients are surgical candidates, and therefore in those cases radiation
oncologists must prescribed a larger area to treat to ensure that none of the cancerous
region is missed. The drawback to this method is the irradiation of more normal tissue than
necessary, which although deemed to have a greater benefit than harm, is not ideal. Secondly,
this research has strong implications in the field of radiation oncology to move towards
patient oriented radiotherapy treatments. If successful, radiation treatment to the liver
could be performed in less treatments because of the confidence given to radiation
oncologists of the cancer location; knowing exactly the healthy liver regions to avoid.
Description:
Preliminary testing has already been performed and proves the notion that to achieve adequate
image quality in a CT imaging phantom, at least 4 times the MRI administration dose would be
required. These conclusions were supported qualitatively by a radiologist, radiation
oncologist, and medical physicist, while also being backed up by quantitative measurement
that has been accepted in the medical imaging literature. It is important for this work to
first ensure that the imaging system is optimized, to have confidence that it will be
successful for patients. Therefore before this study begins, substantial time and effort will
be spent using phantoms and optimizing the imaging parameters and protocol.
The current procedure for a patient that presents with liver cancer begins with a referral
from the patient's primary care physician for stereotactic body radiation therapy (SBRT). A
radiation oncologist makes the decision whether the patient is suitable for SBRT.
If the patient is deemed acceptable by the radiation oncologist, the next step is to undergo
diagnostic imaging so that the radiation oncologist can identify where exactly the disease is
located, and start the SBRT plan. Using the diagnostic images, the radiation oncologist
outlines the areas to treat, as well as the areas that they want to spare. This information
is given to a physicist who then plans the optimal way of delivering radiation based on the
oncologist's specifications. Once the plan is approved by the radiation oncologist, the
patient can be treated.
At the time of treatment, the patient is placed in an immobilization device on a treatment
couch by a radiation therapist. Once the patient is immobilized, an x-ray imaging system that
is attached to the treatment machine extends out towards the patient. The machine performs a
180-degree rotation with continuous x-ray imaging. Once sufficient imaging has been
performed, the therapists then align these images with the previous diagnostic CT image that
was used to plan the radiation treatment. This alignment process tells the radiation
therapists how much to adjust the patient on the treatment couch to ensure the most accurate
treatment delivery. Once the patient is in the proper position, the radiation treatment is
delivered and then the patient can leave.
The treatment procedure is then performed on five separate days each separated by 48 hours.
The proposed research follows the same procedure with addition of a contrast injection at the
treatment stage. A consent form will be given to the patient entailing the purpose of this
study. It will highlight the risks and benefits of receiving contrast prior to the radiation
treatment, as well as a complete outline of the research. If the patient consents to
receiving an intravenous contrast injection of gadoxetate disodium then the treatment
procedure will change as follows:
Before the patient is placed in the immobilization device, a MRI technologist with experience
giving gadoxetate disodium injections will give the prescribed injection according to the
patient's body weight. After the injection is given, a liver SBRT trained radiation therapist
will lead the patient to the treatment machine and set them up in the immobilization device
as per standard treatments. The same time-of-treatment imaging will be performed, with the
hypothesis that the image quality will improve because of the addition of the contrast agent.
The contrast agent will only be administered at the first treatment because of the limited
data on repeat injections of the drug in humans. Furthermore, for the first treatment when
contrast is administered, a radiation oncologist, radiologist, medical physicist, MRI
technologist, and three radiation therapists will attend.
The patient will then be monitored for another 30 minutes with support equipment ready in the
rare event that a side effect occurs.
As per standard treatments, the radiation oncologist will follow up with patients at regular
intervals during and after treatment, making sure to check with the patient for possible side
effects of using the contrast agent.
