Your search keyword '"Dass M"' showing total 3 results

1. DNA Origami Curvature Sensors for Nanoparticle and Vesicle Size Determination with Single-Molecule FRET Readout.

Author

Büber E, Schröder T, Scheckenbach M, Dass M, Franquelim HG, and Tinnefeld P

Subjects

Nanotechnology, DNA chemistry, Cell Membrane, Fluorescence Resonance Energy Transfer, Nanoparticles chemistry

Abstract

Particle size is an important characteristic of materials with a direct effect on their physicochemical features. Besides nanoparticles, particle size and surface curvature are particularly important in the world of lipids and cellular membranes as the cell membrane undergoes conformational changes in many biological processes which leads to diverging local curvature values. On account of that, it is important to develop cost-effective, rapid and sufficiently precise systems that can measure the surface curvature on the nanoscale that can be translated to size for spherical particles. As an alternative approach for particle characterization, we present flexible DNA nanodevices that can adapt to the curvature of the structure they are bound to. The curvature sensors use Fluorescence Resonance Energy Transfer (FRET) as the transduction mechanism on the single-molecule level. The curvature sensors consist of segmented DNA origami structures connected via flexible DNA linkers incorporating a FRET pair. The activity of the sensors was first demonstrated with defined binding to different DNA origami geometries used as templates. Then the DNA origami curvature sensors were applied to measure spherical silica beads having different size, and subsequently on lipid vesicles. With the designed sensors, we could reliably distinguish different sized nanoparticles within a size range of 50-300 nm as well as the bending angle range of 50-180°. This study helps with the development of more advanced modular-curvature sensing devices that are capable of determining the sizes of nanoparticles and biological complexes.

Published

2023

2. DNA Origami Meets Bottom-Up Nanopatterning.

Author

Martynenko IV, Ruider V, Dass M, Liedl T, and Nickels PC

Subjects

Printing, DNA chemistry, Nanotechnology

Abstract

DNA origami has emerged as a powerful molecular breadboard with nanometer resolution that can integrate the world of bottom-up (bio)chemistry with large-scale, macroscopic devices created by top-down lithography. Substituting the top-down patterning with self-assembled colloidal nanoparticles now takes the manufacturing complexity of top-down lithography out of the equation. As a result, the deterministic positioning of single molecules or nanoscale objects on macroscopic arrays is benchtop ready and easily accessible.

Published

2021

3. Chiral Assembly of Gold-Silver Core-Shell Plasmonic Nanorods on DNA Origami with Strong Optical Activity.

Author

Nguyen L, Dass M, Ober MF, Besteiro LV, Wang ZM, Nickel B, Govorov AO, Liedl T, and Heuer-Jungemann A

Subjects

DNA, Gold, Optical Rotation, Silver, Metal Nanoparticles, Nanotubes

Abstract

The spatial organization of metal nanoparticles has become an important tool for manipulating light in nanophotonic applications. Silver nanoparticles, particularly silver nanorods, have excellent plasmonic properties but are prone to oxidation and are therefore inherently unstable in aqueous solutions and salt-containing buffers. Consequently, gold nanoparticles have often been favored, despite their inferior optical performance. Bimetallic, i.e. , gold-silver core-shell nanoparticles, can resolve this issue. We present a method for synthesizing highly stable gold-silver core-shell NRs that are instantaneously functionalized with DNA, enabling chiral self-assembly on DNA origami. The silver shell gives rise to an enhancement of plasmonic properties, reflected here in strongly increased circular dichroism, as compared to pristine gold nanorods. Gold-silver nanorods are ideal candidates for plasmonic sensing with increased sensitivity as needed in pathogen RNA or antibody testing for nonlinear optics and light-funneling applications in surface enhanced Raman spectroscopy. Furthermore, the control of interparticle orientation enables the study of plasmonic phenomena, in particular, synergistic effects arising from plasmonic coupling of such bimetallic systems.

Published

2020