To date, examining patient tissue samples has meant cutting them into thin slices for histological analysis. This might now be set to change - thanks to a new staining method devised by an interdisciplinary team from the Technical University of Munich (TUM). This allows specialists to investigate three-dimensional tissue samples using the Nano-CT system also recently developed at TUM.
Tissue sectioning is a routine procedure in hospitals, for instance to investigate tumors. As the name implies, it entails cutting samples of body tissue into thin slices, then staining them and examining them under a microscope. Medical professionals have long dreamt of the possibility of examining the entire, three-dimensional tissue sample and not just the individual slices. The most obvious way forward here lies in computed tomography (CT) scanning - also a standard method used in everyday clinical workflows.
Previous limitations in resolution and contrast
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Thus far, there have been two major hurdles to the realization of this goal. Firstly, the resolution of conventional CT scanners is too low. Today's Micro- and Nano-CT systems are rarely suitable for use in frontline medicine. Some do not offer sufficiently high resolution, while others rely on radiation from large particle accelerators.
Secondly, soft tissue is notoriously difficult to examine using CT equipment. Samples have to be stained to render them visible in the first place. Stains for CT scanning are sometimes highly toxic, and they are also extremely time-consuming to apply. At times they modify the tissue to such an extent that further analysis is then impossible.
Successful collaboration between physics, chemistry and medicine
Now, however, scientists at TUM's Munich School of BioEngineering (MSB) have solved both problems. In November 2017, Prof. Franz Pfeiffer and his team unveiled a Nano-CT system that delivers resolutions of up to 100 nanometers and is suitable for use in typical laboratory settings. In the current issue of the scientific journal PNAS, the cross-disciplinary research team from physics, chemistry and medicine also presents a staining method for histological examination with Nano-CT.
Compatibility with conventional methods
Using a mouse kidney, the scientists have successfully demonstrated that Nano-CT is able to generate 3D images that match the information granularity of tissue sections. At the core of the staining method lies eosin, a standard dye used in tissue sampling that was previously considered unsuitable for CT.
