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Active HORIZON European Commission

Inexhaustible Spring of Hyperpolarization For Magnetic Resonance

€2.99M EUR

Funder European Commission
Recipient Organization Universite Lyon 1 Claude Bernard
Country France
Start Date Jan 01, 2023
End Date Dec 31, 2027
Duration 1,825 days
Number of Grantees 2
Roles Coordinator; Third Party
Data Source European Commission
Grant ID 101044726
Grant Description

Nuclear magnetic resonance (NMR) has become a well-established and versatile tool in numerous fields of research and in industry, but features a relatively low sensitivity which prevents solving todays most pressing challenges in modern science.Hyperpolarization by dissolution dynamic nuclear polarization (dDNP) provides a partial solution by enhancing sensitivity 10000-fold.

However, hyperpolarized solutions are available only once (single-shot), and are contaminated and diluted.

This is incompatible with most NMR experiments, except for some niche applications.HypFlow will reach the ground-breaking overall aim of providing inexhaustible (multi-shot) and pure (unpolluted and undiluted) hyperpolarization, thus truly compatible with NMR by:1)designing and building a pulsed-DNP freeze&flow polarizer,2) integrating the use of hyperpolarizing matrices with polarized electrons, and3) validating multi-scan applications in metabolomics, drug discovery, and chemistry.Liquid NMR samples will freeze in the HypFlow system where high levels of polarization will be generated, will then melt and flow toward the spectrometer, and will recirculate repeatedly.

This will offer, for the first-time, inexhaustible and pure hyperpolarization with a 10000-fold boost in sensitivity.The PI has a unique combined leading expertise in most recent instrumental, methodological and chemical developments in dDNP that will empower him to tackle the scientific challenges of HypFlow.HypFlow will deepen the fundamental scientific knowledge of nuclear and electron spin polarization generation, transfer, and relaxation phenomena.

It will enable detection of hyperpolarized samples in a fully compatible way with a broad range of NMR applications, radically transforming and democratizing the practice of hyperpolarized NMR in research laboratories and industries.

All Grantees

Universite Lyon 1 Claude Bernard; Centre National de la Recherche Scientifique CNRS

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