SubsidieMeestersPhototransient InfraRed Holography (PIRO)
The PIRO project aims to develop a novel phototransient infrared holographic microscope for rapid, high-resolution imaging of molecular changes in cancer and antibiotic-treated bacteria for improved diagnostics.
Projectdetails
Introduction
Molecules are the fundamental building blocks of life: disease is intrinsically linked to molecular malfunction and, sometimes, a tiny molecular error in a single cell can kill an organism. Drugs, such as antibiotics, are designed to protect us: they rid us of pathogens by disrupting their molecular machinery. If unsuccessful, surviving bacteria might adapt to evade future attacks and a few resistant bacteria can cause great damage.
Importance of Molecular Changes
Everything mentioned above relies on specific molecular changes. A technique that could rapidly visualize them holds great promise: it would allow us to specifically target this one deadly cancer cell or adopt antibiotics treatment before resistance emerges.
Vibrational Imaging Techniques
Vibrational imaging, which combines spatial cues with molecular resolution, is the prime candidate for revealing this molecular stand-off:
- Spontaneous Raman readily acquires broadband spectra but is too slow to interrogate large samples.
- Coherent Raman can measure them but lacks spectral resolution.
- Fourier transform infrared microscopy combines spectral resolution and speed but its spatial resolution is insufficient.
PIRO Project Overview
PIRO promises to deliver the necessary tool for the job by combining concepts from nonlinear ultrafast spectroscopy and digital holography. PIRO implements a novel vibrational imaging platform: a phototransient infrared holographic microscope (PIROscope).
PIROscope Features
The PIROscope, inspired by our recently introduced ultrafast holographic microscope, combines femtosecond IR-excitation with visible readout to, ultimately, retrieve spectrally resolved quantitative images with an unprecedented combination of imaging speed, spectral observation window, and spatial resolution.
Implementation and Goals
During PIRO, we will implement the PIROscope and validate it for biomedical imaging. We will then use our edge over the state-of-the-art to take first steps towards PIRO-based diagnostics by high-resolution visualizing breast cancer tissue and the metabolic activity of antibiotics-treated bacteria.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 1.937.138 |
| Totale projectbegroting | € 1.937.138 |
Tijdlijn
| Startdatum | 1-5-2023 |
| Einddatum | 30-4-2028 |
| Subsidiejaar | 2023 |
Partners & Locaties
Projectpartners
- STICHTING VUpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
| Project | Regeling | Bedrag | Jaar | Actie |
|---|---|---|---|---|
Laser-Based Infrared Vibrational Electric-Field FingerprintingThe LIVE project aims to enhance IR spectroscopy using femtosecond lasers for non-destructive, label-free analysis of biological samples, improving sensitivity and applicability in biomedical settings. | ERC Consolid... | € 1.881.875 | 2023 | Details |
Super-resolution Field-Resolved Stimulated Raman MicroscopyThis project aims to develop a super-resolution, label-free Raman microscope using femtosecond laser technology to non-invasively visualize subcellular structures with unprecedented sensitivity and resolution. | ERC Consolid... | € 1.996.250 | 2025 | Details |
Single-Molecule Acousto-Photonic NanofluidicsSIMPHONICS aims to develop a high-throughput, non-invasive platform for protein fingerprinting by integrating nanopore technology with acoustic manipulation and fluorescence detection. | ERC Starting... | € 1.499.395 | 2022 | Details |
In vivo Immunofluorescence-Optical Coherence TomographyDevelop a high-resolution endoscopic imaging system combining Optical Coherence Tomography and fluorescent antibodies for improved diagnosis and treatment of esophageal cancer and lung disease. | ERC Advanced... | € 2.500.000 | 2025 | Details |
Universal Platform for Infra-Red ImagingUPIRI aims to revolutionize IR visualization by developing a compact nanoscale layer for standard cameras to simultaneously detect all IR bands and convert them to visible light. | ERC Consolid... | € 2.999.999 | 2025 | Details |
Laser-Based Infrared Vibrational Electric-Field Fingerprinting
The LIVE project aims to enhance IR spectroscopy using femtosecond lasers for non-destructive, label-free analysis of biological samples, improving sensitivity and applicability in biomedical settings.
Super-resolution Field-Resolved Stimulated Raman Microscopy
This project aims to develop a super-resolution, label-free Raman microscope using femtosecond laser technology to non-invasively visualize subcellular structures with unprecedented sensitivity and resolution.
Single-Molecule Acousto-Photonic Nanofluidics
SIMPHONICS aims to develop a high-throughput, non-invasive platform for protein fingerprinting by integrating nanopore technology with acoustic manipulation and fluorescence detection.
In vivo Immunofluorescence-Optical Coherence Tomography
Develop a high-resolution endoscopic imaging system combining Optical Coherence Tomography and fluorescent antibodies for improved diagnosis and treatment of esophageal cancer and lung disease.
Universal Platform for Infra-Red Imaging
UPIRI aims to revolutionize IR visualization by developing a compact nanoscale layer for standard cameras to simultaneously detect all IR bands and convert them to visible light.
Vergelijkbare projecten uit andere regelingen
| Project | Regeling | Bedrag | Jaar | Actie |
|---|---|---|---|---|
ulTRafast hOlograPHic FTIR microscopYTROPHY combines advanced microscopy techniques to enable rapid, high-resolution imaging of tumor biopsies for precise diagnosis and tailored cancer therapies, enhancing patient outcomes. | EIC Pathfinder | € 1.904.544 | 2022 | Details |
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Breaking the Resolution Limit in Two-Photon Microscopy Using Negative PhotochromismThis project aims to develop a novel multiphoton microscopy technique that achieves four-photon-like spatial resolution using two-photon absorption, enhancing biomedical imaging capabilities. | EIC Pathfinder | € 2.266.125 | 2023 | Details |
ulTRafast hOlograPHic FTIR microscopY
TROPHY combines advanced microscopy techniques to enable rapid, high-resolution imaging of tumor biopsies for precise diagnosis and tailored cancer therapies, enhancing patient outcomes.
On-chip tomographic microscopy: a paraDIgm Shift for RevolUtionizing lab-on-a-chiP bioimaging technology
DISRUPT aims to revolutionize biomedical imaging with a novel lab-on-chip technology for cost-effective, high-resolution cancer detection and diagnostics using integrated tomographic microscopy and AI.
REAL TIME MOLECULAR IMAGER WITH UNSURPASSED RESOLUTION
RETIMAGER aims to revolutionize PET imaging by achieving ten-fold improvements in spatial and temporal resolution, enabling real-time, high-sensitivity imaging for personalized precision medicine.
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.
Breaking the Resolution Limit in Two-Photon Microscopy Using Negative Photochromism
This project aims to develop a novel multiphoton microscopy technique that achieves four-photon-like spatial resolution using two-photon absorption, enhancing biomedical imaging capabilities.