Innovative electron microscopy

A current central scientific challenge is to understand the molecular machinery underlying cellular function. This knowledge is urgently needed, on the one hand for the development of future technology in the hope that humans can copy some of nature’s design rules, and on the other hand to battle diseases, especially cancer. This challenge requires the development of advanced microscopy techniques to achieve a nanometer scale resolution on proteins within intact cells in their native liquid state.

Our research program aims at finding clues to the causes of drug resistance development in cancer, studying membrane protein interactions at the single molecule level, and exploring dynamic interactions of nanomaterials at the solid-liquid interface. For this purpose, our group’s research generates breakthrough innovations to optimize liquid-phase electron microscopy (LP-EM), 3D scanning transmission electron microscopy (STEM), and in situ STEM.

The team:

The research is conducted by an interdisciplinary team of (bio)physicists, cell biologists, (bio)chemists, and computer scientists in the group Innovative Electron Microscopy (IEM) at the INM – Leibniz Institute for New Materials, in Saarbrücken, Germany. Prof. Dr. Dr. h.c. Niels de Jonge is an expert and pioneer in LP-EM and leads the research team. He is also honorary professor of physics at Saarland University (UdS).

Innovative Electron Microscopy research group, INM, Saarbrücken, Germany.
14.10.2021. Foto Bellhäuser

Announcements:

  • Niels de Jonge is happy to share that he is starting a new position as Head of R&D – Advanced diffraction technology at Bruker AXS!
  • The 2nd Gordon Research Conference on Liquid Phase Electron Microscopy, Ventura, CA, US, Jan. 30 – Feb.4., 2022. link
  • CISCEM 2021 – Hybrid Conference on In-Situ and Correlative Electron Microscopy, 8-10 Sept. 2021, Paris, France and remote. link

Prof. Dr. Dr. h.c. Niels de Jonge
CV
Google Scholar
Web of Science

Highlights:

  • Nanoscale Faceting and Ligand Shell Structure Dominate the Self-Assembly of Nonpolar Nanoparticles into Superlattices. Adv. Mater. 202109093. link see also press release.
  • 2019: Research project on gastric cancer starts, funded by the Deutsche KrebshilfeMetGaP “long-term response in Trastuzumab-treated metastatic gastric- or gastroesophageal junction cancer patients via molecular HER2 surface and pathway analyses”. See projects page.
  • 2019: Paper about the spatial- and temporal resolution of LP-EM published in Nat. Mat. Rev.. link