Dose-efficient multimodal microscopy of human tissue at a hard X-ray nanoprobe beamline.
Simone SalaYuhe ZhangNathaly De La RosaTill DreierMaik KahntMax LangerLars B DahlinMartin BechPablo VillanuevaSebastian KalbfleischPublished in: Journal of synchrotron radiation (2022)
X-ray fluorescence microscopy performed at nanofocusing synchrotron beamlines produces quantitative elemental distribution maps at unprecedented resolution (down to a few tens of nanometres), at the expense of relatively long measuring times and high absorbed doses. In this work, a method was implemented in which fast low-dose in-line holography was used to produce quantitative electron density maps at the mesoscale prior to nanoscale X-ray fluorescence acquisition. These maps ensure more efficient fluorescence scans and the reduction of the total absorbed dose, often relevant for radiation-sensitive (e.g. biological) samples. This multimodal microscopy approach was demonstrated on human sural nerve tissue. The two imaging modes provide complementary information at a comparable resolution, ultimately limited by the focal spot size. The experimental setup presented allows the user to swap between them in a flexible and reproducible fashion, as well as to easily adapt the scanning parameters during an experiment to fine-tune resolution and field of view.
Keyphrases
- high resolution
- single molecule
- atomic force microscopy
- endothelial cells
- living cells
- low dose
- electron microscopy
- high speed
- mass spectrometry
- dual energy
- pluripotent stem cells
- magnetic resonance imaging
- high dose
- energy transfer
- healthcare
- optical coherence tomography
- radiation induced
- health information
- single cell
- solar cells