Clinical Trial Details
— Status: Active, not recruiting
Administrative data
| NCT number |
NCT03358589 |
| Other study ID # |
MESTAR |
| Secondary ID |
|
| Status |
Active, not recruiting |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
September 1, 2017 |
| Est. completion date |
August 31, 2021 |
Study information
| Verified date |
May 2021 |
| Source |
Odense University Hospital |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Background: Despite that up 90% of patients with early-stage breast cancer receives adjuvant
treatment, there are still about 300 patients diagnosed with primary metastatic breast cancer
(MBC) and about 1,200 patients who develop metastases after the primary treatment each year
in Denmark.
Aim: The investigators hypothesize that molecular evaluation with FDG-PET/CT and diffusion
weighted MRI allows an earlier detection of failure to respond to potentially toxic drugs in
patients receiving breast cancer directed treatments.
The aims of our project are to address the following questions:
- Does FDG-PET/CT allow an earlier detection of failure to respond to treatment for MBC
than conventional CT?
- Does FDG-PET/CT or MRI allow an earlier detection of failure to respond to treatment for
bone metastatic disease than conventional CT?
- Does the PET based criteria (PERCIST) have the potential to lead to changes in the
treatment plans made from CT based criteria (RECIST)?
- Does FDG-PET/CT give a more accurate diagnosis of MBC than conventional CT in terms of
number and distribution of metastatic sites?
Method: Part A - the accuracy study: The study population will comprise all women referred to
Odense University Hospital with suspected metastatic breast cancer (MBC). The investigators
expect to include 270 patients who will be examined with FDG-PET/CT. If bone metastases are
detected, the patients will proceed to MRI. All patients with suspected metastases on
FDG-PET/CT or MRI will have a biopsy from a suitable lesion Part B - the response evaluation
study: The investigators expect to include 90 patients with biopsy-verified MBC. Patients
will receive oncologic treatment according to national guidelines. Response to treatment will
be evaluated by conventional CT criteria and compared to novel criteria according to FDG-
PET/CT, and MRI. Test results will be blinded to each other, so that knowledge of other test
results will be unknown for the reader of the CT, FDG-PET/CT or MRI, respectively Expected
clinical impact: This project represents a truly multidisciplinary effort to improve the
diagnosis, staging, and response evaluation of MBC. The investigators hope that patients will
benefit in terms of being spared for ineffective toxic treatment due to earlier detection of
failure to respond, and hence leading to earlier treatment transition. Patients are involved
in the planning and conduct of the project.
Description:
Background Breast cancer is the most frequent malignant disease in Danish women with about
4,500 new cases per year and about 60,000 women living after a diagnosis of breast cancer
(1). After lung cancer, it is the most common cause of death from cancer among Danish women.
Despite that up 90% of patients with early-stage breast cancer receive adjuvant treatment,
there are still about 300 patients diagnosed with primary metastatic breast cancer and about
1,200 patients who develop metastases after the primary treatment each year in Denmark (2).
Clinical guidelines unanimously recommend that diagnostic work-up for metastatic disease
should be performed only when clinically indicated, or prior to primary treatment in patients
at high risk of MBC, but they do not make clear recommendations on which diagnostic tool to
apply for staging patients with suspected MBC (3-5). The investigators have shown recently
that the molecular whole body imaging with FDG-PET/CT has a higher accuracy than conventional
imaging with CT and bone scintigraphy when diagnosing MBC (6); the investigators results are
in accordance with existing meta-analyses (7,8), and a recent review (9).The gold standard
for verifying MBC is a biopsy from a metastatic lesion, but treatment decisions are often
based on the biomarker profile of the primary tumor, since it has been assumed to remain the
same in the corresponding metastatic lesions. The investigators own data (10) supported by a
meta-analysis (11) point towards discordances between the primary tumor and the corresponding
metastasis ranging from 9% to 23% for expression of estrogen receptors (ER), Human Epidermal
growth factor receptor 2 (HER-2), and Topoisomerase 2A (TOP2A).
It is essential to know the exact baseline stage of MBC in order to allow adequate evaluation
of treatment response subsequently. Response evaluation criteria have traditionally been
based on the morphological size of solid tumors as in the Response Evaluation Criteria in
Solid Tumors (RECIST)(12). The investigators consider it important to include changes in
metabolic activity for evaluation of treatment response, since metabolic changes occur before
morphological changes can be detected. The PET response Criteria in Solid Tumors (PERCIST) is
a new standardized method to assess quantitatively the metabolic tumor response as seen on
FDG-PET/CT (13). A recent pooled analysis and review comparing the PERCIST to the RECIST
criteria concluded that the PERCIST criteria seem to be more suitable for assessing tumor
response than the RECIST criteria, but that the role of the PERCIST criteria needs to be
validated in relevant clinical settings (14).
Monitoring response to therapy in skeletal metastases has been challenging because the RECIST
criteria do not include changes in bony structures though the RECIST 1.1 accepts bone
metastases with soft tissue masses measuring >= 10 mm as a target lesion (15). Up to 70% of
patients with MBC present with bone involvement, characterized as osteolytic, osteoblastic,
or mixed lesions on CT. Soft tissue metastases in the bone marrow may be overlooked by
conventional imaging, but magnetic resonance imaging (MRI) has shown high accuracy for
diagnosing bone and bone marrow metastases (16, 17). Molecular imaging with FDG-PET/CT and
diffusion weighted MRI both have the potential to detect metabolic activity in all types of
bone and bone marrow lesions, and therefore a combination of FDG-PET/CT and whole body MRI
(WBMRI) may give valuable information in assessing metastatic processes in bone.
Aim The investigators hypothesize that
•Molecular evaluation can provide a more accurate assessment of the metastatic spread than
conventional methods and that molecular evaluation of response to breast cancer directed
treatments allows an earlier detection of failure to respond to potentially toxic drugs.
The aims of the project are to address the following questions:
- Does FDG-PET/CT allow an earlier detection of failure to respond to treatment for MBC
than conventional CT?
- Does FDG-PET/CT or MRI allow an earlier detection of failure to respond to treatment for
bone metastatic disease than conventional CT?
- Does the PET based criteria (PERCIST) have the potential to lead to changes in the
treatment plans made from CT based criteria (RECIST)?
- Does FDG-PET/CT give a more accurate diagnosis of MBC than conventional CT in terms of
number and distribution of metastatic sites?
Method The project is divided into 2 parts. Part A - the accuracy study: The study population
will comprise all women referred to Odense University Hospital (OUH) with a suspected first
recurrence of breast cancer and newly diagnosed breast cancer at high risk of metastatic
spread. Data will be collected from about 270 patients over a 2-year period (Figure 1) All
patients will be examined by FDG- PET/CT with contrast enhanced CT in diagnostic quality at
baseline. If bone metastases are detected, the patients will proceed to WBMRI. All patients
with suspected metastases on FDG-PET/CT or WBMRI will have a biopsy from a suitable lesion.
The tissue from the biopsy will be for standard diagnostic procedures, including
immunohistochemistry for biomarkers (ER, HER-2).
All non- metastatic patients will be followed for one year by medical records to detect
potentially false negatives.
Part B - the response evaluation study: The response evaluation part is planned as a
longitudinal cohort design analyzing change of management and prediction og progression free
survival. It will include about 90 patients expected to present with biopsy-verified MBC
during the inclusion period. (Figure 1).
Patients will receive oncologic treatment directed by the biomarker profile of the biopsy and
according to national guidelines. Response to treatment will be evaluated by FDG-PET/CT with
contrast enhanced CT in diagnostic quality after three series of chemotherapy (every 9 weeks)
or after 3 months of endocrine therapy (every 12 weeks). Patients with bone metastases will
be evaluated by WBMRI as well. Lesion based sensitivity analyses will be made for FDG-PET/CT
and for diagnostic CT, and in patients with bone involvement also for WBMRI. A radiologist
will apply the RECIST criteria from the CT and dedicated diffusion measurements from the MRI,
while a Nuclear Medicine Physician will apply the PERCIST criteria along with other relevant
quantitative measures. Test results will be blinded to each other, so that knowledge of other
test results will be unknown for the reader of the CT, FDG-PET/CT or MRI, respectively.
Treatment decisions will be made in a multidisciplinary conference form. Decisions will be
based on the conventional imaging criteria (RECIST) in the first 30 patients, and for each
patient the decision will be reconsidered by the PERCIST criteria and the metabolic
measurements. Discrepancies in decisions guided by the different evaluation criteria will be
registered and analyzed with regard to change of management in an interim analysis. The same
will be done for the succeeding evaluations, but the choice of response evaluation criteria
to guide clinical decision will depend on the result of the interim analysis.
The investigators plan the data collection in a way that allows us to perform
cost-effectiveness analyses for the response evaluation study.
