Add to ORKGA new method to perform simultaneously three dimensional optical sectioning and optical manipulation is presented. The system combines a multi trap optical tweezers with a video microscope to enable axial scanning of living cells while maintaining the trapping configuration at a fixed position. This is achieved compensating the axial movement of the objective by shaping the wave front of the trapping beam with properly diffractive optical elements displayed on a computer controlled spatial light modulator. Our method has been validated in three different experimental configurations. In the first, we decouple the position of a trapping plane from the axial movements of the objective and perform optical sectioning of a circle of beads kept on...
We will demonstrate how optical tweezers can be combined with a microfluidic system to create a vers...
Optical tweezers allow for noninvasive manipulation of subcellular compartments to study their physi...
AbstractThe contact-free, non-invasive manipulation provided by optical trapping enables us not only...
A new method to perform simultaneously three dimensional optical sectioning and optical manipulation...
A new method to perform simultaneously three dimensional optical sectioning and optical manipulation...
We present an experimental system based on the use of a spatial light modulator which enables to per...
The goal of this work is to investigate the usefulness of the optical tweezers for biological sample...
Fluorescent observation of cells generally suffers from the limited axial resolution due to the elon...
We present the possibility to trap cells (mouse fibroblasts, bovine spermatozoa and diatoms), to man...
A significant challenge for in vivo imaging is to remove movement artifacts. These movements (typica...
Imaging non-adherent cells by super-resolution far-field fluorescence microscopy is currently not po...
We will demonstrate how optical tweezers can be combined with a microfluidic system to create a vers...
Optical tweezers allow for noninvasive manipulation of subcellular compartments to study their physi...
AbstractThe contact-free, non-invasive manipulation provided by optical trapping enables us not only...
A new method to perform simultaneously three dimensional optical sectioning and optical manipulation...
A new method to perform simultaneously three dimensional optical sectioning and optical manipulation...
We present an experimental system based on the use of a spatial light modulator which enables to per...
The goal of this work is to investigate the usefulness of the optical tweezers for biological sample...
Fluorescent observation of cells generally suffers from the limited axial resolution due to the elon...
We present the possibility to trap cells (mouse fibroblasts, bovine spermatozoa and diatoms), to man...
A significant challenge for in vivo imaging is to remove movement artifacts. These movements (typica...
Imaging non-adherent cells by super-resolution far-field fluorescence microscopy is currently not po...
We will demonstrate how optical tweezers can be combined with a microfluidic system to create a vers...
Optical tweezers allow for noninvasive manipulation of subcellular compartments to study their physi...
AbstractThe contact-free, non-invasive manipulation provided by optical trapping enables us not only...