This study involves a breathing motion assessment in healthy subjects before and after continuous positive airway pressure (CPAP) administration using MRI images. The hypothesis for this study is that CPAP administration will significantly reduce breathing motion. This may help cancer patients who are undergoing proton radiotherapy, so they possibly will not have to hold their breath during the procedure.
Minimally invasive techniques for tumor motion reduction that involve free-breathing patients have significant relevance in the context of radiation therapy, in particular proton radiotherapy. Tumor motion reduction has favorable implications for reduction of radiation doses to adjacent healthy organs, radiation plan robustness (accuracy/quality) and for treatment efficiency (reduction of treatment times). Using non-ionizing MRI with volunteers, the investigators will determine the extent to which continuous positive airway pressure (CPAP) reduces breathing motion (diaphragmatic excursion). The researchers will also investigate the parameter space associated with breathing motion reduction versus the amount of pressure applied, as well as timing of initiation of CPAP in relation to the imaging time point (to address whether an initial transient breathing state exists).
Study Type
INTERVENTIONAL
Allocation
NA
Purpose
BASIC_SCIENCE
Masking
NONE
Enrollment
10
CPAP requires subjects to wear a plastic pressurized mask/apparatus, which is connected via a filter and hose to a pump capable of supplying variable pressure (typically on the range of 4-20 cm H2O). The investigators plan to use a full-face mask to prevent subjects from reducing pressure by opening their mouths. If this cannot be tolerated or properly fitted, or is not compatible with the CPAP ventilator, subjects would use a nasal mask only and be asked to keep their mouths closed.
Mayo Clinic in Rochester
Rochester, Minnesota, United States
Change in Breathing Motion Characteristics at High CPAP Setting
Breathing motion at baseline and at initial (higher but tolerable) CPAP settings will be characterized using fast multi-slice, multi-phase 2D gradient-echo or spin-echo MRI sequences in the sagittal or coronal imaging planes over a large field of view covering the thoracic and upper-abdominal region. Specifically "4D-MRI" (or time-resolved MRI) will be generated from retrospective sorting of multi-slice 2D MRI. For these analyses, anatomic reference points (e.g., bright vessels) in multiple organ systems will be identified on the images, contoured or segmented; subsequently 3D motion patterns will be extracted for all anatomical references/features. Numerical simulations will be performed to determine hypothetical radiation target volume changes (cm\^3) at these anatomic locations assuming spherical tumors with a given set of tumor diameters (cm).
Time frame: Data acquisition for this portion of the study will require approximately 30 minutes.
Change in Breathing Motion Characteristics at Lower CPAP Setting
Time permitting, the CPAP setting will be reduced to approximately half of the nominal/tolerable/high CPAP setting. Using the same MRI sequences and retrospective sorting technique, 4D-MRI will be generated for this lower CPAP setting. Analogous motion characterization analyses (to outcome measure 1) will be carried out for the lower CPAP setting (relative to baseline 4D-MRI).
Time frame: Approximately 45 minutes into visit.
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