Scientists led by the ESRF, UGA and INSERM have developed cryo-correlative nano-imaging, a new technique that combines lab cryo-fluorescence microscopy, cryo X-ray fluorescence nanoimaging and phase-contrast nano-tomography on ID16A. The results are published in ACS Nano.
Biologists have long wanted to answer a deceptively simple question: what are the structures we see inside cells actually made of? Visible light fluorescence microscopy shows where organelles are, but not their chemical composition. Hard X-rays can map the chemistry but do not necessarily see the organelles. Cryo-correlative nanoprobe work remains rare, particularly for 3D elemental imaging of whole frozen cells.
A new study at ID16A beamline of the ESRF offers a practical solution. An international team has developed an integrated cryogenic workflow that links laboratory cryo-fluorescence microscopy to targeted cryo X-ray fluorescence (XRF) nano-imaging and phase-contrast nano-tomography.
With this new method, they have tracked therapeutic nanoparticles from the European ScanNtreat project as they moved through cancer cells, showing both where the particles went and what happened to them.
The first author of the publication, Dmitry Karpov, former ESRF scientist and now researcher at the Université Grenoble Alpes, explains how this new development can lead to applications: “This is an example of what the ESRF aims to do: to turn cutting-edge instrumentation into discoveries with direct impact on people’s lives, in this case for medicine and life sciences”.
Read more on the ESRF website