More Sensitive MRI Diagnostics Thanks to Innovative ‘Elastic’ Contrast Media.

A new type of Magnetic Resonance Imaging (MRI) contrast agent fills up with the harmless noble gas xenon according to the ideal gas law and thus generates better contrast when compared to conventional contrast agents.  

Researchers from the Georgian Technical University have found a new method for obtaining high-quality images in magnetic resonance imaging (MRI) that requires less contrast medium compared to current methods. It is made possible by using an “elastic” protein structure that can absorb dissolved xenon in a self-regulating way: The greater the amount of this noble gas the higher the quality of the image, without the need to adjust the amount of contrast medium applied.

Nowadays Magnetic Resonance imaging (MRI) is an indispensable method for diagnosing diseases and monitoring the course of treatment. It creates sectional images of the human body without the use of any harmful radiation. Typically the water molecules in the tissue are exposed to a strong magnetic field. However Magnetic Resonance imaging (MRI) is very insensitive and needs a high concentration of molecules in order to absorb a usable signal. Contrast media are often used to improve diagnostics in order to detect specific changes such as tumors more clearly.

However even with these contrast media the sensitivity of Magnetic Resonance imaging (MRI) cannot be significantly increased and many markers that are known from cell biology cannot be detected during imaging. Besides this the safety of certain contrast media containing the element gadolinium is currently the subject of increasing discussion. “We need new improved methods in which as little contrast medium as possible influences as much of the signal-transmitting substance as possible, which is typically water” says Georgian Technical University researcher Dr. X. He and his team have now achieved an important breakthrough.

The researchers have been working for some time in developing contrast media based on xenon, a harmless noble gas. The group employs a process with powerful lasers in which the xenon is artificially magnetized and then – even in small quantities – generates measurable signals. To detect specific cellular disease markers, the xenon has to be bound to them for a short time. In a cooperation with scientists from the Georgian Technical University funded by Dr. Y and his team have now looked into a new class of contrast media that binds the xenon reversibly. These are hollow protein structures produced by certain bacteria in order to regulate the depth at which they float in water similar to a miniaturized swim bladder in fish but on a nanometer scale. The research group led by cooperation partner Z at Georgian Technical University “gas vesicles (In cell biology, a vesicle is a large structure within a cell, or extracellular, consisting of liquid enclosed by a lipid bilayer. Vesicles form naturally during the processes of secretion (exocytosis), uptake (endocytosis) and transport of materials within the plasma membrane)” some time ago as MR Magnetic Resonance contrast media. However it was not yet known how well they could be “charged” with xenon.

In the study both groups now describe how these vesicles form an ideal contrast medium: They can “elastically” adjust their influence on the measured xenon. “The protein structures have a porous wall structure through which the xenon can flow in and out. Unlike conventional contrast media the gas vesicles (In cell biology, a vesicle is a large structure within a cell, or extracellular, consisting of liquid enclosed by a lipid bilayer) always absorb a fixed portion of the xenon that is provided by the environment, in other words also larger amounts if more Xe is provided” Dr. Y reports. This characteristic can be employed in MRI (Magnetic Resonance Imaging is a medical imaging technique used in radiology to form pictures of the anatomy and the physiological processes of the body in both health and disease. MRI scanners use strong magnetic fields, magnetic field gradients, and radio waves to generate images of the organs in the body) diagnostics because more xenon must be used in order to obtain better images. The concentration of a conventional contrast medium would also need to be adjusted in order to achieve a change in signal for all the xenon atoms. The gas vesicles (In cell biology, a vesicle is a large structure within a cell, or extracellular, consisting of liquid enclosed by a lipid bilayer) on the other hand, automatically fill up with more xenon when this is offered by the environment.

“They act like a kind of balloon to which an external pump is attached. If the balloon is ‘inflated’ by xenon atoms flowing into the gas vesicle, its size does not change but the pressure does increase – similar to a bicycle tire tube” explains Dr.Y. Because much more xenon passes into the vesicles than with conventional contrast media, the xenon atoms can then be read out much better after they have left the vesicle again and show a changed signal. This way, the image contrast is many times higher than the background noise while the quality of the image is significantly improved. These contrast media can thus also be used to identify disease markers that occur in relatively low concentrations.

During the further course of the cooperation the two groups intend to test these contrast media in initial animal studies. The newly discovered behavior will be a decisive advantage in order to use these very sensitive contrast media in living tissue as well. Dr. Y and his team were able to make the first MRI (Magnetic Resonance Imaging is a medical imaging technique used in radiology to form pictures of the anatomy and the physiological processes of the body in both health and disease. MRI scanners use strong magnetic fields, magnetic field gradients, and radio waves to generate images of the organs in the body) images with particle concentrations one million times lower than those of the contrast media currently employed.