SubsidieMeestersMultimodal quantitative phase microscopy
The MultiPhase project aims to enhance quadriwave lateral shearing interferometry by retrieving polarization information of light for improved applications in nanophotonics and biomicroscopy.
Projectdetails
Introduction
Quantitative phase microscopies (QPMs) experienced a strong gain of interest this last decade, especially for bioimaging applications. Mapping the phase of a light beam enables biologists to enhance the contrast of live cells in culture without invasive fluorescent labeling.
Capabilities of QPMs
It also enables the unprecedented capability of QPMs to accurately measure the biomass of live cells observed by optical microscopy. This capability, out of reach using fluorescence microscopy, yields an accurate control of the growth rate of cells in culture.
Quadriwave Lateral Shearing Interferometry
Quadriwave lateral shearing interferometry is a high-resolution wavefront sensing technique that has been used as a QPM for 10 years. It represents a simple, yet robust and accurate, QPM that has already been applied not only in biology, but also in nanophotonics for the first time, by the PI, to characterize objects such as:
- Nanoparticles
- 2D materials
- Metasurfaces
This expands the range of application of QLSI.
Limitations of QLSI
However, like any other QPM technique, QLSI is based on the assumption that the imaged light field is scalar. While this assumption is fine for some applications, for others, it yields a loss of information because QPMs do not capture the whole information a beam can contain.
MultiPhase Project Objectives
In the MultiPhase project, we wish to expand the capabilities of QLSI by developing an experimental methodology to retrieve the polarization information of the light field, in intensity and phase.
Testing and Software Development
The applicability of this new methodology will be tested and illustrated by conducting proof-of-concept experiments related to applications in nanophotonics and biomicroscopy. Finally, a software to pilot the system will be developed.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 150.000 |
| Totale projectbegroting | € 150.000 |
Tijdlijn
| Startdatum | 1-11-2022 |
| Einddatum | 30-4-2024 |
| Subsidiejaar | 2022 |
Partners & Locaties
Projectpartners
- CENTRE NATIONAL DE LA RECHERCHE SCIENTIFIQUE CNRSpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
| Project | Regeling | Bedrag | Jaar | Actie |
|---|---|---|---|---|
Structuring Quantum Light for MicroscopySQiMic aims to revolutionize optical microscopy by integrating quantum imaging and light structuring to enhance imaging of unlabeled biological specimens with improved resolution and contrast. | ERC Starting... | € 1.499.365 | 2022 | Details |
Quantum-enhanced nonlinear imagingQuNIm aims to revolutionize deep-tissue imaging using quantum entanglement to enhance resolution and penetration while minimizing tissue damage, impacting neuroscience and beyond. | ERC Consolid... | € 1.979.704 | 2024 | Details |
A light-efficient microscope for fast volumetric imaging of photon starved samplesLowLiteScope aims to revolutionize bioluminescence microscopy by using AI-driven light field techniques for high-resolution 3D imaging of biological samples, enhancing research capabilities in life sciences. | ERC Proof of... | € 150.000 | 2024 | Details |
Lightsheet Brillouin Nanoscopy: mechano-sensitive superresolution imaging for regenerative medicineThis project aims to develop Lightsheet Brillouin Nanoscopy (LiBriNa), a groundbreaking microscopy technique for imaging viscoelasticity in living cardiac tissues at unprecedented speed and resolution. | ERC Starting... | € 1.807.313 | 2025 | Details |
Time-based single molecule nanolocalization for live cell imagingThe project aims to develop a novel live-cell nanoscopy technique that enables high-speed, high-resolution imaging of biological processes at the nanoscale without compromising depth or volume. | ERC Advanced... | € 2.498.196 | 2023 | Details |
Structuring Quantum Light for Microscopy
SQiMic aims to revolutionize optical microscopy by integrating quantum imaging and light structuring to enhance imaging of unlabeled biological specimens with improved resolution and contrast.
Quantum-enhanced nonlinear imaging
QuNIm aims to revolutionize deep-tissue imaging using quantum entanglement to enhance resolution and penetration while minimizing tissue damage, impacting neuroscience and beyond.
A light-efficient microscope for fast volumetric imaging of photon starved samples
LowLiteScope aims to revolutionize bioluminescence microscopy by using AI-driven light field techniques for high-resolution 3D imaging of biological samples, enhancing research capabilities in life sciences.
Lightsheet Brillouin Nanoscopy: mechano-sensitive superresolution imaging for regenerative medicine
This project aims to develop Lightsheet Brillouin Nanoscopy (LiBriNa), a groundbreaking microscopy technique for imaging viscoelasticity in living cardiac tissues at unprecedented speed and resolution.
Time-based single molecule nanolocalization for live cell imaging
The project aims to develop a novel live-cell nanoscopy technique that enables high-speed, high-resolution imaging of biological processes at the nanoscale without compromising depth or volume.
Vergelijkbare projecten uit andere regelingen
| Project | Regeling | Bedrag | Jaar | Actie |
|---|---|---|---|---|
Development of an In-Vivo Brillouin Microscope (with application to Protein Aggregation-based Pathologies)This project aims to enhance Brillouin Microscopy for real-time, non-destructive assessment of viscoelastic properties in living cells, addressing key biomedical challenges. | EIC Pathfinder | € 3.333.513 | 2023 | Details |
The world’s most sensitive absorption microscopeQlibriNANO aims to validate and enhance the world's most sensitive absorption microscope for nanoscale matter analysis, targeting market readiness and scalability by 2027. | EIC Transition | € 2.480.000 | 2024 | Details |
Development of an In-Vivo Brillouin Microscope (with application to Protein Aggregation-based Pathologies)
This project aims to enhance Brillouin Microscopy for real-time, non-destructive assessment of viscoelastic properties in living cells, addressing key biomedical challenges.
The world’s most sensitive absorption microscope
QlibriNANO aims to validate and enhance the world's most sensitive absorption microscope for nanoscale matter analysis, targeting market readiness and scalability by 2027.