Skip to main content

From surrogate hemodynamics-based fMRI towards direct functional imaging of neural activity via sensing activity-induced cell swellings and neurotransmitter releases in vivo

Objective

Functional-Magnetic Resonance Imaging (fMRI) has transformed our understanding of brain function due to its ability to noninvasively tag ‘active’ brain regions. Nevertheless, fMRI only detects neural activity indirectly, by relying on slow hemodynamic couplings whose relationships with underlying neural activity are not fully known.

We have recently pioneered two unique MR approaches: Non-Uniform Oscillating-Gradient Spin-Echo (NOGSE) MRI and Relaxation Enhanced MR Spectroscopy (RE MRS). NOGSE-MRI is an exquisite microstructural probe, sensing cell sizes (l) with an unprecedented l^6 sensitivity (compared to l^2 in conventional approaches); RE MRS is a new spectral technique capable of recording metabolic signals with extraordinary fidelity at ultrahigh fields.

This proposal aims to harness these novel concepts for mapping neural activity directly, without relying on hemodynamics.

The specific objectives of this proposal are:
(1) Mapping neural activity via sensing cell swellings upon activity: we hypothesize that NOGSE-fMRI can robustly sense subtle changes in cellular microstructure upon neural firings and hence convey neural activity directly.
(2) Probing the nature of elicited activity via detection of neurotransmitter release: we posit that RE MRS is sufficiently sensitive to robustly detect changes in Glutamate and GABA signals upon activation.
(3) Investigating widespread neural circuits in vivo via stroboscopic optogenetics: we propose to couple NOGSE-fMRI with optogenetics to resolve casual dynamics in global neural circuitry.

Simulations for NOGSE-fMRI predict >4% signal changes upon subtle cell swellings; further, our in vivo RE MRS experiments have detected metabolites with SNR>50 in only 6 seconds. Hence, these two complementary –and importantly, hemodynamics-independent– approaches will represent a true paradigm shift: from indirect detection of neurovasculature couplings towards direct and noninvasive mapping of neural activity in vivo.

Field of science

  • /natural sciences/chemical sciences/analytical chemistry/spectroscopy

Call for proposal

H2020-MSCA-IF-2014
See other projects for this call

Funding Scheme

MSCA-IF-EF-ST - Standard EF

Coordinator

FUNDACAO D. ANNA SOMMER CHAMPALIMAUD E DR. CARLOS MONTEZ CHAMPALIMAUD
Address
Avenida Brasilia, Centro De Investigacao Da Fundacao Champalimaud
1400-038 Lisboa
Portugal
Activity type
Research Organisations
EU contribution
€ 160 635,60