Clinical Trial Finder

Inclusion Criteria:

1. Participants male and female aged 8 years old and older. 2. Participants have no smoking history. 3. For participants with CF and asthma, a clinical diagnosis is necessary and they should be at their baseline level of symptom control based on history. 4. Participants should have a FEV1%pred value greater than 40%. 5. Participant understands the study procedures and is willing to participate in the study as indicated by signature on the informed consent or assent. 6. Participant must be able to perform a breath hold for 16s. 7. Participant able to perform reproducible pulmonary function tests (i.e., the 3 best acceptable spirograms have FEV1 values that do not vary more than 5% of the largest value or more than 100 ml, whichever is greater).

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  Exclusion Criteria:

  1.

Participant is, in the opinion of the investigator, mentally or legally incapacitated, preventing informed consent/assent from being obtained, or cannot read or understand the written material. 2. Participant has a history of cardiovascular disorders including coronary insufficiency, cardiac arrhythmias, severe hypertension. 3. Participant has had a cold or respiratory infection in the last four weeks. 4. Participant requires supplemental oxygen or has a daytime room air oxygen saturation ≤ 95%. 5. Participant is unable to perform spirometry or plethysmography maneuvers. 6. Participant is pregnant or lactating. 7. In the investigator's opinion, participant suffers from any physical, psychological or other condition(s) that might prevent performance of the MRI, such as severe claustrophobia. 8. Participant has an MRI incompatible device or any metal in their body which cannot be removed, including but not limited to pacemakers, neurostimulators, biostimulators, implanted insulin pumps, aneurysm clips, bio prosthetic, artificial limb, metallic fragment or foreign body, shunt, surgical staples (including clips or metallic sutures and/or ear implants). -

Hyperpolarized noble gas magnetic resonance (MR) lung imaging is a relatively new imaging method that allows depiction of both lung function and morphology. Hyperpolarized gases are a new class of MR contrast agent which, when inhaled, provide high temporal and spatial resolution MR images of the lung airspaces. Since no ionizing radiation is involved, hyperpolarized gas MR imaging is ideal for the evaluation of lung diseases especially in children. With hyperpolarized gases, the nuclear spins of the gas atoms are brought into alignment outside of the MR scanner via a process called optical pumping; this yields high polarizations and permits visualization of the lung airspaces with MR imaging (despite the low physical density of the gas in the lung). Two non-radioactive (i.e. stable) isotopes of noble gases helium-3 and xenon-129 can be hyperpolarized. Until recently, higher polarizations could be achieved with helium-3 than with xenon-129, so in humans, helium-3 was more commonly used for hyperpolarized gas MR imaging of the lungs. Recently, the technology has been developed to provide large quantities of highly polarized xenon-129. Helium-3 gas is also extremely expensive and since there are limited reserves of the gas, difficult to procure for research. Unlike helium-3, since xenon-129 is naturally present in the atmosphere, it is less expensive and easier to procure for imaging. Several applications of xenon-129 MR imaging are under development, including diffusion-weighted and relaxation-weighted imaging. These techniques take advantage of the fact that the rate of loss of xenon-129 polarization is significantly influenced by the local blood flow and concentration of molecular oxygen, as well as the restriction of xenon-129 diffusion by small airway space dimensions. These data can be used to create maps of the lung reflecting regional ventilation/perfusion and micro-airway sizes. Other data that can be obtained with xenon-129 MRI include the volumes of ventilated and unventilated lungs which can subsequently be analyzed to determine the homogeneity of gas distribution within the airspaces. These data can be used to study the structural and functional changes taking place in the lungs associated with pulmonary diseases like CF and asthma. It might provide a diagnostic tool that is able to detect pulmonary diseases more sensitively than the current gold standard measurements of spirometry and plethysmography, and thus prevent irreparable and irreversible damage to the lungs in the early stages of disease.

Arms

Active Comparator: Healthy

Healthy Participants ages 8 and older. Participants with inhale hyperpolarized xenon-129 which is used as a contrast agent for lung imaging. Participants will undergo magnetic resonance imaging and lung clearance index.

Active Comparator: Cystic Fibrisos

Participants with cystic fibrosis ages 8 and older.Participants with inhale hyperpolarized xenon-129 which is used as a contrast agent for lung imaging. Participants will undergo magnetic resonance imaging and lung clearance index.

Active Comparator: Asthma

Participants with asthma ages 8 and older.Participants with inhale hyperpolarized xenon-129 which is used as a contrast agent for lung imaging. Participants will undergo magnetic resonance imaging and lung clearance index.

Interventions

Drug: - Xenon-129

Xenon gas to be inhaled by research participants

Device: - Magnetic Resonance Imaging

Lung imaging will be performed for participants using MRI for all 3 arms

Device: - Lung Clearance Index

Lung clearance index (measure of lung health) will be performed for all participants of all 3 arms