CORDIS
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Multimodal, Functional Bio-Photonic Imaging

Multimodal, Functional Bio-Photonic Imaging

Ziel

FBI fosters education of ESRs on an emerging, multimodal imaging platform and its translation into clinical and biological applications. In FBI, 15 ESRs are trained at world-leading European academic institutions and companies, thus forming strong interdisciplinary relations between industry, technical sciences and clinical end-users.

Optical imaging has huge potential to address unmet clinical needs by combining non-invasive and real-time capture of biomedical information; thus enabling earlier onset of treatment, reduced therapy costs, reduced recurrence rates, and improved clinical outcomes. Up to now, optical modalities were applied as standalone techniques each targeting one biomarker. Recently it has been shown that diagnosis is significantly improved by combining different contrast mechanisms simultaneously in a multimodal approach, i.e., staging and grading of lesions is feasible.

FBI proposes to combine a selection of modalities depending on the targeted disease. Suspicious lesions are analysed with optical coherence tomography, optoacoustic tomography, multi-photon tomography, and Raman spectroscopy to provide morphological, label-free microangiography, and intrinsic biochemical information, respectively. An important issue is the need for endoscopy: combining said modalities into endoscopes is challenging due to the integration of different imaging concepts, scanning and detection methods, and laser sources. Accordingly, there is a huge need for effectively translating these technical solutions to industry and clinics, which traditionally is restricted by lack of understanding of applications or limited knowledge of new technology.

All these barriers are addressed by FBI through research and development of novel photonic components and systems, through educating ESRs in understanding clinical, biological and commercial challenges, and through developing tailored technical solutions and efficient translation of technology within a strong network.
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Koordinator

DANMARKS TEKNISKE UNIVERSITET

Adresse

Anker Engelundsvej 1 Bygning 101 A
2800 Kgs Lyngby

Dänemark

Aktivitätstyp

Higher or Secondary Education Establishments

EU-Beitrag

€ 580 163,76

Beteiligte (9)

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TECHNISCHE UNIVERSITAET MUENCHEN

Deutschland

EU-Beitrag

€ 498 432,96

TECHNISCHE UNIVERSITEIT EINDHOVEN

Niederlande

EU-Beitrag

€ 510 748,56

ECOLE POLYTECHNIQUE FEDERALE DE LAUSANNE

Schweiz

EU-Beitrag

€ 530 453,52

MEDIZINISCHE UNIVERSITAET WIEN

Österreich

EU-Beitrag

€ 767 802,24

NKT PHOTONICS A/S

Dänemark

EU-Beitrag

€ 290 081,88

PHILIPS ELECTRONICS NEDERLAND B.V.

Niederlande

EU-Beitrag

€ 255 374,28

FEMTOLASERS PRODUKTIONS GMBH

Österreich

ITHERA MEDICAL GMBH

Deutschland

EU-Beitrag

€ 249 216,48

EKSPLA UAB

Litauen

EU-Beitrag

€ 220 442,76

Partner (5)

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SMART PHOTONICS BV

IMASONIC SAS

CARL ZEISS AG

ALBERT-LUDWIGS-UNIVERSITAET FREIBURG

Academisch Medisch Centrum bij de Universiteit van Amsterdam

Projektinformationen

ID Finanzhilfevereinbarung: 721766

Status

Laufendes Projekt

  • Startdatum

    1 Oktober 2016

  • Enddatum

    30 September 2020

Finanziert unter:

H2020-EU.1.3.1.

  • Gesamtbudget:

    € 3 902 716,44

  • EU-Beitrag

    € 3 902 716,44

Koordiniert durch:

DANMARKS TEKNISKE UNIVERSITET

Dänemark