Clinical Trial Details
— Status: Recruiting
Administrative data
| NCT number |
NCT06012500 |
| Other study ID # |
2021-0031 |
| Secondary ID |
|
| Status |
Recruiting |
| Phase |
|
| First received |
|
| Last updated |
|
| Start date |
April 14, 2022 |
| Est. completion date |
March 30, 2026 |
Study information
| Verified date |
August 2023 |
| Source |
Children's Hospital Medical Center, Cincinnati |
| Contact |
Ashley Bordon, MS |
| Phone |
513-636-0143 |
| Email |
Ashley.Bordon[@]cchmc.org |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Observational
|
Clinical Trial Summary
The purpose of this multi-centered, NIH-sponsored study is to to develop an optimal protocol
for using non-invasive 129Xe gas exchange MRI to detect changing disease activity in
interstitial lung diseases (ILDs). We base this study on the demonstrated promise of 129Xe as
a biomarker for both prognosis and therapy response, overwhelming interest from both industry
and academic partners, and impending FDA approval for 129Xe ventilation MRI. This requires
disseminating standardized and repeatable methods for 3D 129Xe functional MRI in order to
facilitate innovative multi-center observational and interventional trials that can advance
our understanding of fibrotic lung disease, while accelerating the development of novel
therapies.
Description:
There remains an urgent need to better phenotype interstitial lung diseases, predict
trajectories, monitor progression, and measure treatment response. Because ILD pathology is
spatially and temporarly heterogeneous, the problem demands a 3-dimensional (3D) lung
assessment. To this end, CT imaging patterns are critical in IPF diagnosis, but such
structural imaging is insensitive to changing functional status. Thus, we have developed
hyperpolarized (HP) 129Xe MRI, whose unique properties enable rapid, non-invasive, 3D
functional assessment of inhaled gas distribu-tion in the airspaces, as well as its uptake in
the pulmonary interstitium (barrier tissues) and trans-fer to the pulmonary capillary red
blood cells (RBCs). This way of probing regional gas exchange confers sensitivity to
micron-scale interstitial barrier thickening and locally diminished RBC trans-fer. We have
used 129Xe MRI to predict outcomes such as death or the need for transplant and have provided
preliminary evidence showing that barrier uptake is a sensitive and early marker of therapy
response. These advancements have led to demands for wider dissemination, which drives an
urgent need to harmonize acquisition protocols and quantification methods.
This work will be conducted by 4 collaborating centers - Duke University, the University of
Cin-cinnati, Cincinnati Children's Hospital Medical Center, and the University of Wisconsin.
Cincin-nati Children's will operate under its own IRB protocol and IND, but each will share
data and im-aging techniques in order to establish best practices. The specific aims of the
work are:
Aim 1 - Maximize and Measure Repeatability of 129Xe MRI/MRS Metrics across MRI Platforms. We
will improve upon published repeatability of ±15-20% by harmonizing MRI/MRS protocols by
improved coaching, optimized dose delivery, and tailoring the inhaled dose volume to the
individ-ual patient. Using these approaches, each center will demonstrate coefficients of
repeatability of ±6% or better in patients with ILD.
Aim 2 - Establish Harmonized Quantitative Analysis of Gas Exchange MRI/MRS. We will deploy a
reconstruction and analysis package enabling users of any of three major MRI vendor
plat-forms to obtain robust, real-time quantitative analysis of images and spectra. We will
demon-strate that healthy reference cohorts are equivalent to ±10% across 4 centers and use
this to build the definitive multi-site healthy reference distributions.
Aim 3 - Deploy a Clinical Framework to Identify Active Fibrosis and Normal Aging. To position
the technology for clinical deployment and interpretation, we will develop a physiologic
model incorporating ventilation, barrier and RBC metrics to explain the underlying factors
responsible for a given patient's diffusing capacity (DLCO) and transfer coefficient (KCO).
This framework will be deployed to readers who will differentiate ILD from normal aging.
The expected outcomes are to 1) deploy robust and standardized acquisition and analysis
proto-cols across centers and scanner platforms, 2) establish the methods and standards for
maximiz-ing repeatability of each gas exchange imaging metric, and 3) provide the tools and
framework needed to use 129Xe MRI to characterize disease and assess therapeutic efficacy.
Collectively, this program will enable rapid and innovative trials that will accelerate
progress in studying and treating fibrotic lung disease. While this technical development
study is focused on healthy sub-jects and those with ILD, deployment of these non-invasive
MRI methods should benefit the study of interstitial lung disease more broadly, as well as
other conditions of gas exchange im-pairment such as pulmonary vascular disease, COPD, and
COVID-19.
