Clinical Trial Details
— Status: Enrolling by invitation
Administrative data
| NCT number |
NCT04831138 |
| Other study ID # |
STU 032018-078 |
| Secondary ID |
|
| Status |
Enrolling by invitation |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
March 24, 2021 |
| Est. completion date |
March 24, 2027 |
Study information
| Verified date |
April 2024 |
| Source |
University of Texas Southwestern Medical Center |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Magnetic Resonance Imaging (MRI) including Arterial Spin Labeling (ASL) will be performed
before, during, and after the treatment, in a total of up to 6 MRI sessions until 7 months
after the first session, or when progression is clinically indicated. Thereafter, patients
will be followed through standard clinical examinations for the next 3 years or until demise,
whichever occurs first.
Clinically, metastatic renal cell carcinoma (RCC) patients are imaged every 2-3 months after
the initiation of anti-angiogenic therapy, since morphological (i.e. size) changes are not
anticipated earlier. However, our preliminary experience has shown functional changes
including perfusion as early as 2-weeks after the initiation of the treatment. T0, T1, and T2
sessions will be performed for this proposal, while T3, T4, and T5 will be performed along
with the clinical imaging sessions. All MR imaging sessions will be scheduled within ±1 or ±2
weeks of the target time period.
The research MR imaging may take approximately an additional 15 minutes per each imaging
session, when done in conjunction with the clinical imaging. The T0, T1, and T2 research MR
imaging sessions will be performed additionally for the purpose of this study, with each
taking approximately one hour.
Description:
The incidence of kidney cancer has steadily increased over the past three to four decades and
is among the 10 most frequently diagnosed cancers in the US. Approximately 63,990 new cases
of kidney cancer are estimated in 2017 and the prognosis has been historically poor. The
current 5-year survival rates are estimated at 74% overall, decreasing to 53% among patients
with locally advanced diseases.
The most common form of kidney cancer, renal cell carcinoma (RCC), occurs in 90% of all
kidney cancers. Among patients with localized RCC who are treated with nephrectomy,
approximately one quarter have relapses in distant sites. Among patients with metastatic RCC,
the 5-year survival rates are approximately 8%. With better understanding of the pathogenesis
of the most common type of RCC, clear-cell renal cell carcinoma (ccRCC), newer treatment
options with new agents are being developed to increase survival rates.
The high cost and potential risks associated with human trials for the newly developed
experimental therapies have emphasized the need for sensitive monitoring of tumor response.
Imaging approaches can play an important role in the evaluation and selection of potential
new therapies with non-invasive longitudinal monitoring of treatment response. Currently, the
radiological assessment of treatment outcomes predominantly relies on morphological (i.e.
size) changes using the Response Evaluation Criteria in Solid Tumors (RECIST) and other
similar scores. This is a major limiting factor as the effects of many therapeutic agents at
the microscopic level precede the eventual changes in tumor size. One such tumor property
that has gained increased attention is angiogenesis, which has been shown to support tumor
proliferation and infiltration. Increasing numbers of clinical trials have begun targeting
tumor vascular supplies by directly inhibiting angiogenesis (e.g. antiangiogenic therapy).
Such clinical trials and the eventual clinical use of these therapies would be greatly
assisted by the availability of robust imaging indicators of angiogenesis (i.e. tissue
perfusion).
Positron Emission Tomography (PET) using 15O-labeled water (15O-PET) is considered the gold
standard for non-invasive measurement of tissue perfusion. However, the use of 15O-PET
requires a cyclotron in close proximity to PET to produce short lived 15O-water (half life
2.4 min), limiting its applicability in clinical settings. Alternative imaging techniques
include ultrasound using microbubbles, perfusion computed tomography (CT) using iodinated
contrast agent and perfusion MRI using gadolinium based contrast agents. All of these
techniques require exogenous agents, restricting their use in longitudinal monitoring of
treatment response.
ASL-MRI has recently emerged as a quantitative imaging (QI) method to measure perfusion (or
capillary blood flow) without the administration of exogenous contrast agents. ASL
magnetically "labels" the highly permeable water in the blood as a tracer and measures their
accumulation in the tissue of interest, without injecting any exogeneous contrast. Various
versions of ASL have been validated in animals using microspheres, and in humans using
15O-PET in the brain. ASL also has a number of advantages compared to dynamic contrast
enhanced (DCE) and dynamic susceptibility contrast (DSC) based MR perfusion measurements.
Specifically, ASL does not require exogenous agent alleviating the concerns of gadolinium
accumulation or nephrogenic systemic fibrosis (NSF) in patients with impaired renal function
and, unlike DCE/DSC, the contribution of vascular permeability to ASL measured perfusion is
negligible enabling absolute perfusion quantification in physiological units.
