Marie-Eve Aubin-Tam (Associate Professor, BioNanoscience) uses single-molecule tools to study membrane proteins and cell biophysics. Research: (1) optical tweezers protein unfolding β mechanical unfolding of membrane proteins to probe folding landscape; (2) single-molecule cell biophysics β force spectroscopy on live cells; (3) synthetic biology applications β integrating engineered proteins with biophysical tools.
Poul Martin Bendix (Associate Professor, BendixLab/NBI) investigates physical properties of living cells using advanced optical techniques. Research: (1) optical tweezers for mechanosensing β GPCR mechanosensing with picoNewton force resolution, membrane curvature sensing by proteins (annexins, BAR-domain proteins); (2) thermoplasmonics β gold nanoparticle laser heating for controlled membrane microsurgery, cell fusion, and plasma membrane repair; (3) single-molecule biophysics β DNA-protein interactions using 4-trap optical tweezers (LUMICKS C-Trap) with STED imaging; (4) filopodia dynamics β twist and rotation of actin filaments; (5) Brillouin microscopy for cell mechanics; (6) COBM center management. GPCRmec consortium (Novo Nordisk). 2026 BPS Annual Meeting featured.
Cees Dekker (Distinguished University Professor, BioNanoscience/Kavli) pioneered solid-state nanopores and single-molecule biophysics. Research: (1) solid-state nanopores for protein sensing and sequencing β detecting individual protein molecules by current blockade; (2) DNA loop extrusion by condensin and cohesin at the single-molecule level; (3) chromatin structure and chromosome organisation with bacteria-on-chip; (4) synthetic cell construction from the bottom up; (5) diagnostic nanopores for neglected diseases. NanoFront 51Mβ¬ NWO program leader; 2019 Nature paper on real-time DNA loop extrusion imaging.
Nynke Dekker (Full Professor, BioNanoscience) leads single-molecule biophysics of DNA replication and topology. Research: (1) single-molecule force-fluorescence microscopy β integrated optical tweezers and fluorescence for real-time imaging of replication machinery; (2) DNA topology β supercoiling, gyrase, topoisomerase dynamics with magnetic tweezers; (3) DNA/RNA-processing molecular motors. EMBO member; KNAW member. 2024 integrated force-fluorescence toolbox published.
Marileen Dogterom (Full Professor, BioNanoscience) studies cytoskeleton dynamics and synthetic cell construction. Research: (1) microtubule dynamics β force generation, catastrophe control, and mitotic spindle assembly reconstituted in vitro; (2) cell division reconstitution β building minimal synthetic cells with controlled division; (3) optical tweezers and fluorescence microscopy for force measurement on single cytoskeletal elements. Co-founded BioNanoscience department.
Kristin GruΓmayer (Assistant Professor, BioNanoscience, 2021) develops super-resolution microscopy tools. Research: (1) SOFI (super-resolution optical fluctuation imaging) β camera-based super-resolution using photon statistics; (2) multi-plane super-resolution and quantitative phase imaging β combined modalities for 3D sub-diffraction imaging; (3) new fluorescence probe classes for SMLM; (4) AI-driven smart microscopy for automated phenotype detection. Marie Curie Fellow (EPFL, Lasser group). Group established 2021.
Thomas Heimburg (Professor, NBI Membranes group) works on thermodynamics and biophysics of biological membranes. Research: (1) theory of nerve pulse propagation as electromechanical solitons ('soliton model'); (2) lipid membrane phase transitions β calorimetry, DSC, AFM; (3) anesthesia mechanism via membrane phase perturbation; (4) ion-channel-like events in pure lipid membranes near phase transitions. Notably co-authored 2016 Scientific Reports paper with QUANTOP (Jensen et al.) demonstrating non-invasive detection of nerve impulses using atomic magnetometry β direct overlap with quantum sensing.
Arjen Jakobi (Associate Professor, BioNanoscience) uses cryo-electron microscopy and tomography for structural cell biology. Research: (1) cryo-ET in-cell structural biology β resolving protein complexes at near-atomic resolution inside vitrified cells; (2) autophagy and membrane remodelling β structural mechanism of autophagosome biogenesis; (3) integrin signalling complexes. Develops algorithms for sub-tomogram averaging and de-novo model building.
Chirlmin Joo (Full Professor, BioNanoscience) uses single-molecule fluorescence to study RNA dynamics and CRISPR-Cas. Research: (1) single-molecule FRET and direct RNA imaging β visualizing RNA folding, ribozyme catalysis, and mRNA translation dynamics; (2) CRISPR-Cas mechanism β real-time observation of Cas9 and Cas13 target search and cleavage; (3) nanopore-based protein sensing integration with optical tools. ERC Grant.
Gijsje Koenderink (Full Professor, BioNanoscience) investigates active and passive mechanics of the cytoskeleton. Research: (1) active matter β motor-filament composite networks generating spontaneous mechanical activity; (2) cell mechanics β cytoskeletal contributions to cell shape, migration, and division; (3) biomaterials β designing synthetic cytoskeletal analogues; (4) optical tweezers and AFM rheology of reconstituted networks. Spinoza Prize 2021. ERC Advanced Grant.