We investigated subclasses of living peripheral blood cells in a microfluidic-based system, with the aim to characterize their morphometric and optical properties, and to track their position in flow in a label-free modality. We employed two coherent imaging techniques: a scattering approach of precisely aligned single cells, and a digital holography approach to achieve optical cell reconstructions in flow. Cells were first 3D-aligned in round shaped capillary and subsequently measured in a following square shaped channel. Results were obtained at two fixed measurement positions, the first one was chosen close to the entrance of the measurement channel to ensure 3D cell alignment for scattering investigations; the second was placed 15 mm af...
: Live cells act as biological lenses and can be employed as real-world optical components in bio-hy...
This dissertation demonstrates the development of a portable and low cost lab-on-a-chip flow cytomet...
A major challenge in the field of optical imaging of live cells is achieving rapid, 3D, and noninvas...
We implemented a completely label-free biophysical (morphometric and optical) property characterizat...
The investigation of the physical properties of peripheral blood mononuclear cells (PBMC) is of grea...
Cell of human blood stream are divided into two groups: Red Blood Cells (RBC) and White Blood Cells ...
A camera-based light scattering approach coupled with a viscoelasticity-induced cell migration techn...
The Light Scattering Profile (LSP) of an individual cell provides a fast and accurate characterizati...
We combine confocal imaging, microfluidics, and image analysis to record 3D-images of cells in flow....
We report a rapid and cost-effective system to analyze morphological properties and 3D alignment pos...
High-throughput single-cell analysis is a challenging task. Label-free tomographic phase microscopy ...
Morphological detailed informations of living blood cell are retrieved with an approach based on lig...
Holographic tomography allows the 3D mapping of the refractive index of biological samples thanks to...
Traditional tomographic reconstruction methods are based on the knowledge of illumination directions...
The refractive index of biological specimens is a source of intrinsic contrast that can be explored ...
: Live cells act as biological lenses and can be employed as real-world optical components in bio-hy...
This dissertation demonstrates the development of a portable and low cost lab-on-a-chip flow cytomet...
A major challenge in the field of optical imaging of live cells is achieving rapid, 3D, and noninvas...
We implemented a completely label-free biophysical (morphometric and optical) property characterizat...
The investigation of the physical properties of peripheral blood mononuclear cells (PBMC) is of grea...
Cell of human blood stream are divided into two groups: Red Blood Cells (RBC) and White Blood Cells ...
A camera-based light scattering approach coupled with a viscoelasticity-induced cell migration techn...
The Light Scattering Profile (LSP) of an individual cell provides a fast and accurate characterizati...
We combine confocal imaging, microfluidics, and image analysis to record 3D-images of cells in flow....
We report a rapid and cost-effective system to analyze morphological properties and 3D alignment pos...
High-throughput single-cell analysis is a challenging task. Label-free tomographic phase microscopy ...
Morphological detailed informations of living blood cell are retrieved with an approach based on lig...
Holographic tomography allows the 3D mapping of the refractive index of biological samples thanks to...
Traditional tomographic reconstruction methods are based on the knowledge of illumination directions...
The refractive index of biological specimens is a source of intrinsic contrast that can be explored ...
: Live cells act as biological lenses and can be employed as real-world optical components in bio-hy...
This dissertation demonstrates the development of a portable and low cost lab-on-a-chip flow cytomet...
A major challenge in the field of optical imaging of live cells is achieving rapid, 3D, and noninvas...