I take inspiration from Nature´s extraordinary ability to design structures with ultimate precision. Particularly, I am fascinated by tiny, invisible to naked eye, yet powerful organisms, such as virus particles. They follow the principle of economy, efficiency and error-free structure formation at multiple length scales using sub-unit based self-assembly. To achieve this goal, I use nanoparticles that are atomically precise and develop methods to prepare new generation two dimensional (2D) nanosheets, synthetic hollow capsids, nanowires for application in optics, photonics, catalysis and sensing. Simulataneously, I am also developing Extracellular matrix (ECM) and nanoscaffold design for breast cancer therapy. Finally, I use cryo-Transmission Electron Microscopy (TEM) and Electron Tomography to visualize structures at atomic resolution.

Research Fields

2D Materials Active Pharmaceutical Ingredients actuators Agarose gel bile acid bile acids Bionanotechnology Block copolymers Bone Growth Factors Bone Mineralization Breast cancer Cancer biomarker Cancer Cell Capsids Carbon Nanotubes Catalysis Cellulose Nanocrystals Chemical Sciences Chromosome structure Cocrystals collagen Colloidal Valence Colloid and Surface Chemistry conducting polymer Cryo-electron microscopy Crystal Engineering Crystal growth Crystallography dendrimerosomes DNA nanotechnology DOSY NMR Spectroscopy Double network gels drug delivery devices Dynamic light scattering Enamine reaction ER positive cancer excitons Extracellular Matrix Fluorescence Graphene haogen bonding Hyaluronic acid gels hydrogel Hydrophobin In-situ Microscopy Liquid Crystals Luminescent complexes Metallic Biomaterials metal-organic framework Metal organic framework micelles Nacre mimetics nanocellulose Nanochemistry and Supramolecular Chemistry Nanomedicine Nanoparticle Functionalization Nanostructures NMR Crystallography NMR diffusion NMR spectroscopy Organic Synthesis organocatalysis Patchy Nanoparticles Physical Sciences Plasmonics Plasmonic waveguides polymer brushes Polymer Composites and Nanocomposites polymers Polymrosphism powder diffraction Protein Crystallogra Protein engineering protein-nanoparticle interactions Protein Self-assembly Quantum Nanoclusters quantum nanomaterials Self-Assembly self-assembly of peptide Sensors Silk-mimetics Silk protein self-assembly small-angle X-ray scattering Solid-State NMR Spider silk steroids Subcomponent self-assembly Superatomic Clusters Superhydrophobisity supracolloidal assembly Supramolecular Chemistry Supramolecular Gels supramolecular polymers Supraparticles Synthetic Biology synthetic supramolecular chemistry TNBC cancer Tomography transmission electron microscopy Vesicles Virus Virus particles x-ray crystallography

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