Although traditional MRI is already widely used, hyperpolarized MRI is a more recent development—and its research and application potential has yet to be fully explored. Researchers at Johannes Gutenberg University Mainz (JGU) and the Helmholtz Institute Mainz (HIM) in Germany have now unveiled a new technique for observing metabolic processes in the body. Specifically, their singlet-contrast MRI method employs easily produced parahydrogen to track biochemical processes in real time.
“MRI images can show us the structure of the brain, for example, but they tell us nothing about the biomolecular processes occurring in the body, partly because of the poor sensitivity of MRI,” says James Eills, PhD, first author of the study and member of the work group led by Professor Dmitry Budker at JGU and HIM.
Using Hydrogen Atoms Instead of Carbon or Nitrogen Isotopes
One way to significantly enhance MRI signals is hyperpolarization. This achieves significant alignment of the signal-generating nuclear spins with the help of an external magnetic field. Hyperpolarization-enhanced MRI is already being used to study biomolecular processes in the body; unfortunately, the use of carbon isotope C-13 or the nitrogen isotope N-15 is associated with certain disadvantages.
“It would thus be of considerable benefit if we could use hydrogen atoms directly. Hydrogen has greater sensitivity, is more abundant, and the detection equipment is readily available,” says Eills. A drawback of hydrogen, however, is its rapid relaxation time. This means the hyperpolarized atoms revert to their original state so quickly that it is difficult to generate images.
Eills and his colleagues tackled this problem by using a special quantum state of hydrogen nuclei called a singlet state, which derives from so-called parahydrogen. “This means we were able to overcome the drawbacks of hyperpolarized proton imaging, particularly those relating to the short relaxation time,” says Eills.
While hydrogen usually has a relaxation time of a few seconds, this can be minutes in the case of singlet states. The singlet state is also non-magnetic and therefore cannot be observed. It can only be observed once the molecule is no longer symmetrical.
When Fumarate Is Used, Metabolism Triggers Hyperpolarization
In the study under discussion, the scientists describe their technique for singlet-contrast MRI using fumarate, a biomolecule naturally occurring as an intermediate product of metabolism. First, fumarate is produced from a precursor molecule and parahydrogen.
The hyperpolarized fumarate is converted into malate by the addition of a heavy water molecule. This conversion eliminates the symmetry of the molecule, rendering it magnetic and detectable. “Then we can use the associated magnetic signals for imaging,” Eills says.
Carbon-13-labelled fumarate is already a molecule that plays a significant role in hyperpolarized imaging. This work opens the possibility to perform fumarate-imaging with all the benefits of observing hydrogen rather than cabon-13. Moreover, use of parahydrogen would also be beneficial due to the fact that it can be easily produced: Hydrogen gas is simply cooled in the presence of a catalyst, which is then removed. The resulting parahydrogen can then be warmed up and remains stable in the para state for months.
“Hyperpolarized MRI is in the early stages of its development, and our contribution is an exciting new MRI variant,” concludes Eills. It is possible to record images of the hyperpolarized signal at different points in time, which enables the real-time tracking of metabolic processes.