Elemental mapping of surface-modified nanoparticles using cryo-EELS imaging. (Bottom left) The conventional cryo-TEM image reveals the size, shape, and dispersion state of the nanoparticles. (Top right) In the silicon mapping, silicon from the silica nanoparticles is clearly detected and visualized. (Bottom right) In the carbon mapping, carbon originating from the surface-modifying proteins is visualized, along with carbon from the supporting film on the grid. Credit: Daisuke Unabara et al

Cryo-transmission electron microscopy (cryo-TEM) allows us to observe samples in a preserved state that is close to their native form, making it a highly effective way to examine biological samples. This technique provides information on the size, shape, and dispersion of samples within a frozen solvent. However, there is another crucial piece of information that has not been accurately visualized in organic samples using this technique yet: elemental composition.

Energy-filtered TEM (EF-TEM) can determine the by using (EELS), but it has its shortcomings. The conventional EELS/EF-TEM method can significantly damage the sample and usually exhibits drift—which results in a blurry image. Furthermore, conventional observations have primarily been applied to metals or large-area samples, rather than to organic nanomaterials.

To overcome these limitations, researchers at Tohoku University developed a novel elemental mapping technique using cryo-EELS/EF-TEM, enabling simultaneous visualization of both the structure and elemental distribution of nanomaterials in frozen solvents. This new approach allows high-resolution analysis of organic and bio-related materials. The findings were in Analytical Chemistry on July 31, 2025.

The team found that plasmon signals from ice strongly increased the background signal—an undesirable effect since they are focused on the organic sample and aren't interested in signals from the ice itself. To remedy this, the team developed a new imaging method combining the 3-window method for accurate background correction with drift compensation techniques. Additionally, a new program was created for the "ParallEM" electron microscope control system, allowing easy control of energy shift during imaging.

Elemental mapping of hydroxyapatite particles using cryo-EELS imaging. (Left) The conventional cryo-TEM image shows the size, shape, and dispersion of the hydroxyapatite particles. (Center and right) Calcium and phosphorus—constituent elements of hydroxyapatite—are successfully detected and visualized. Credit: Daisuke Unabara et al

Using this technique, the team successfully visualized silicon distribution in silica nanoparticles within a frozen solvent, alongside their structure and dispersion. The smallest particle size detectable via elemental mapping was determined to be around 10 nm.

The method was also applied to hydroxyapatite particles, a major component of bones and teeth, revealing calcium and phosphorus distributions—key biological elements.

This technique is expected to enable advanced analysis of various materials, including biomaterials, medical materials, food, catalysts, and inks. As such, it can contribute to research across fields from life sciences to materials science.

More information: Daisuke Unabara et al, Low-Dose Elemental Mapping of Light Atoms in Liquid-phase Materials Using Cryo-EELS, Analytical Chemistry (2025).

Journal information: Analytical Chemistry

Provided by Tohoku University