Summary
Viral infections diagnosis demands novel, cheaper and rapid technologies to overcome present constraints. Current gold standard for diagnosis of viral infections is based on pathogen-targeted nucleic acid identification; thus, it cannot discern infectious stages from latent ones and it demands time consuming adjustments when mutations occur or new emerging viruses are to be included in the diagnostic protocols. Lately, optomechanics has served to fundamental advancements in physics, from gravitational wave detection to the study of mechanical quantum ground states but it has not yet delivered its full applicability potential.
VIRUSCAN aims to apply frontier advancements in optomechanics to the biosensing and diagnostic fields and to create a new interdisciplinary research community with the goal to advance optomechanics, nanoelectromechanics, native mass spectrometry and biophysics towards clinical applications.
VIRUSCAN will provide a novel technology capable to identify viral particles and asses their infective potential through the characterization of two physical parameters: mass and stiffness. Stiffness of viral particles has been recently known to act as a regulator of their infectivity at different stages of the virus life cycle. In parallel, advancements in nanoelectromechanical systems have recently demonstrated that stiffness and mass information from nanoscale adsorbates can be disentangled. Targeting intrinsic physical properties of viral particles will allow developing an open platform that will tackle any virus and their mutations.
VIRUSCAN will have impact at all levels by: providing a personalized treatment to the patients, reducing the use of not effective antibiotics, increasing safety in blood transfusions, allowing a quick and trustworthy response to emergency situations (e.g. recent EBOLA in West Africa and the ZIKA in Brazil), reducing the spread of viral infections, reducing costs per analysis and screening of a wide range of pathogens.
VIRUSCAN aims to apply frontier advancements in optomechanics to the biosensing and diagnostic fields and to create a new interdisciplinary research community with the goal to advance optomechanics, nanoelectromechanics, native mass spectrometry and biophysics towards clinical applications.
VIRUSCAN will provide a novel technology capable to identify viral particles and asses their infective potential through the characterization of two physical parameters: mass and stiffness. Stiffness of viral particles has been recently known to act as a regulator of their infectivity at different stages of the virus life cycle. In parallel, advancements in nanoelectromechanical systems have recently demonstrated that stiffness and mass information from nanoscale adsorbates can be disentangled. Targeting intrinsic physical properties of viral particles will allow developing an open platform that will tackle any virus and their mutations.
VIRUSCAN will have impact at all levels by: providing a personalized treatment to the patients, reducing the use of not effective antibiotics, increasing safety in blood transfusions, allowing a quick and trustworthy response to emergency situations (e.g. recent EBOLA in West Africa and the ZIKA in Brazil), reducing the spread of viral infections, reducing costs per analysis and screening of a wide range of pathogens.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/731868 |
| Start date: | 01-11-2016 |
| End date: | 30-04-2022 |
| Total budget - Public funding: | 7 148 586,25 Euro - 7 148 586,00 Euro |
Cordis data
Original description
Viral infections diagnosis demands novel, cheaper and rapid technologies to overcome present constraints. Current gold standard for diagnosis of viral infections is based on pathogen-targeted nucleic acid identification; thus, it cannot discern infectious stages from latent ones and it demands time consuming adjustments when mutations occur or new emerging viruses are to be included in the diagnostic protocols. Lately, optomechanics has served to fundamental advancements in physics, from gravitational wave detection to the study of mechanical quantum ground states but it has not yet delivered its full applicability potential.VIRUSCAN aims to apply frontier advancements in optomechanics to the biosensing and diagnostic fields and to create a new interdisciplinary research community with the goal to advance optomechanics, nanoelectromechanics, native mass spectrometry and biophysics towards clinical applications.
VIRUSCAN will provide a novel technology capable to identify viral particles and asses their infective potential through the characterization of two physical parameters: mass and stiffness. Stiffness of viral particles has been recently known to act as a regulator of their infectivity at different stages of the virus life cycle. In parallel, advancements in nanoelectromechanical systems have recently demonstrated that stiffness and mass information from nanoscale adsorbates can be disentangled. Targeting intrinsic physical properties of viral particles will allow developing an open platform that will tackle any virus and their mutations.
VIRUSCAN will have impact at all levels by: providing a personalized treatment to the patients, reducing the use of not effective antibiotics, increasing safety in blood transfusions, allowing a quick and trustworthy response to emergency situations (e.g. recent EBOLA in West Africa and the ZIKA in Brazil), reducing the spread of viral infections, reducing costs per analysis and screening of a wide range of pathogens.
Status
CLOSEDCall topic
FETPROACT-01-2016Update Date
27-04-2024
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Organisations
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| AGENCIA ESTATAL CONSEJO SUPERIOR DE INVESTIGACIONES CIENTIFICAS (Coördinator)
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| CENTRE NATIONAL DE LA RECHERCHE SCIENTIFIQUE (CNRS)
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| COMMISSARIAT A L ENERGIE ATOMIQUE ET AUX ENERGIES ALTERNATIVES (CEA)
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| FASMATECH EPISTIMONIKI KAI TECHNOLOGIKI ANONYMI ETAIREIA
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| LEIBNIZ-INSTITUT FUR VIROLOGIE
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| RIJKSUNIVERSITEIT GRONINGEN (RUG)
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| SERVICIO MADRILENO DE SALUD
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| TNO - Nederlandse Organisatie voor Toegepast Natuurwetenschappelijk Onderzoek
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| UNIVERSITE PARIS CITE