Coronary Artery Disease Clinical Trial
Official title:
Validation of PET-MRI for Cardiovascular Disease
To determine whether PET-MRI can obtain comparable images to PET-CT in those with coronary artery disease.
Positron emission tomography (PET) is method of non-invasively imaging a metabolic process.
It has been used in clinical medicine for many years with its primary use in identifying
areas of increased metabolic activity as possible cancers. It involves the use of a
radionuclide (or radiotracer) labelled to a chemical involved in a certain metabolic process.
In order for the PET signal from the radiotracer to be detected by the scanner the
radionuclide emits a small dose of ionizing radiation. Examples of commonly used
radionuclides include 18FDG and 18 Sodium Fluoride (18NaF). In order to locate where exactly
these areas of abnormal or increased metabolic activity were, Computerised Tomography (CT)
has traditionally been used for anatomical correlation.
Until recently PET-CT has largely been confined for use in oncology. More recently however
PET-CT has been utilized to detect vulnerable plaques in those with coronary artery disease.
In coronary artery disease 18F-fluoride acts as a marker of novel calcification activity
within the plaque. Similar to other conditions, calcification in coronary atheroma occurs as
a healing response to intense necrotic inflammation, making 18F- fluoride a useful marker of
high-risk atherosclerotic plaque. This has been demonstrated in those with stable angina as
well as localizing the culprit plaque in those with myocardial infarction in 90% of cases.
Magnetic resonance imaging is being increasingly adopted in cardiovascular imaging and holds
particular attraction due to its ability to provide information about soft tissue structures
both with and without contrast agents, as well as its safety due to absence of exposure to
ionising radiation and rapid imaging speed, which is useful in a moving organ like the heart.
PET-MR works differently to PET-CT. PET relies on the annihilation of protons with electrons,
generating 511 keV photons, which are absorbed in bodily tissues differently depending on
their electron density (e.g. heart denser than lungs). Because of this PET images can appear
brighter or darker in different tissues. To account for this, a technique of attenuation
correction is employed. This is usually in the form of what is called a transmission scan
(low intensity CT scan) which grades tissue density and corrects the PET signal accordingly.
Given MRI measures proton density and not electron density different attenuation correction
techniques are needed. It has not yet been established how best to do this despite multiple
efforts using differing techniques.
Previous single centre studies have demonstrated the feasibility of MRI-PET. The technique's
translation to clinical practice has been limited due to the global lack of reliable
attenuation correction methods. During his recent Clinical Research Imaging Fellowship in New
York, co-investigator (Dr Dweck) developed a novel free breathing method of attenuation
correction in a combined PET-MR scanner that reduced scanning time and improved efficiency
and has shown immense promise. In Edinburgh a similar combined PET-MR scanner (mMR, Siemens,
Erlangen, Germany) has been installed, but have not yet replicated or validated this
technique. If the investigators can demonstrate and apply a method of attenuation correction
that is acceptable and shows good comparability of MRI-PET to PET-CT images they may be able
to use this imaging method as an alternative to PET-CT.
Benefits which may translate clinically include superior soft tissue characterisation and
significantly reduced radiation dosages. The technique could be applied across a range of
medical conditions in addition to cardiovascular disease and oncology.
The investigators are hopeful to establish a suitable attenuation correction method so that
PET-MR can match or even supersede PET-CT as an imaging technique providing accurate
biological, anatomical and functional information in those with cardiovascular disease with
low radiation doses.
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