There’s an imaging technique that’s been emerging over the last ten or so years called imaging mass spectrometry, which can tell you where a whole bunch of different molecules are in tissue all in one go! Basically, you take a slice of the tissue you want to image, apply a chemical resin to it (which is called a “matrix”), and then you shine a fairly strong laser at the tissue. This causes a physical reaction in which the resin absorbs the laser, ionizes, and causes molecules from the tissue to get ejected into the air. The mass spectrometer then sucks those ejected molecules into its cavernous depths and weighs them, breaks them apart, and then weighs their fragments to try to identify what the molecules are. For proteins, this identification process is actually quite easily done.

What you end up with is a really remarkable picture, a 2D map of where a range of different molecules are in the slice of tissue. You can look at the distribution of molecules of different specific weights across the entire slice. By stacking images of adjacent slices, you can then reconstruct an approximate 3D map of where molecules are in a tissue, like a brain or a tumor. Pretty neat!

A section of a mouse brain imaged for molecules of various weight (from Stoeckli et al. (2001) Nature Medicine 7, 493–496.)

Up until now, there have been two main ways to see macromolecules like proteins and RNA in biological tissue. First, you can look at where a specific macromolecule is by sticking a fluorescent dye to it and looking for that “tag.” It’s a great technique, but it’s also pretty laborious and limited in scope, because you can only examine at most three or four things at a time or the colors will start overlapping together a little too much to reliably distinguish what you’re looking at. In addition, you have to know what molecules you’re interested in first in order to tag them.

Second, you can look at cells as a whole using high energy techniques like transmission electron microscopy (TEM), which uses beams of electrons to “X-ray” cells. Since electrons have a very short wavelength, that means that they can be blocked and scattered even by very small structures, including groups of proteins, which means that a TEM image can look at a lot of things with an insanely high amount of detail. Unfortunately, electron microscopy won’t really tell you what you’re looking at, though there are a few techniques (like sticking gold beads to stuff you’re interested in) that try to get around that. Nonetheless, it doesn’t tell you much besides the overall “visual” picture.

Imaging mass spectrometry gets over a lot of these hurdles of traditional microscopy by directly associating molecular weights with specific coordinates in a tissue sample. And because the mass spectrum measures a wide range of weights, a computer algorithm can potentially tease out patterns that might not have occurred to a researcher or doctor looking for a few things at a time. The amount of information that can be obtained from a simple mass spectrum image is tremendous. With newer, cheaper super-accuracy mass spectrometers coming out, such as the orbitrap, this technology is growing in popularity outside of specialized physics labs, and it promises to revolutionize the way a lot of science and medicine is done. In the clinic, for example, a ton more information could come out of a biopsy all at once using this technology, from identifying cancer markers to positively identifying infectious agents and inflammation. I look forward to what’s coming in the future!