Institut de Neurosciences Cognitives et Intégratives d'Aquitaine (UMR5287)

Aquitaine Institute for Cognitive and Integrative Neuroscience



INCIA - UMR 5287- CNRS
Université de Bordeaux

Zone nord Bat 2 2ème étage
146, rue Léo Saignat
33076 Bordeaux cedex
France

Téléphone 05.57.57.15.51
Télécopie 05.56.90.14.21

Supervisory authorities

CNRS Ecole Pratique des Hautes Etudes Université de Bordeaux

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Neurocampus Unitéde Formation de Biologie

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Role of astrocyte aquaporin-4 in brain structure remodeling after traumatic brain injury: a combined MRI and STED microscopy study

by Loïc Grattier - published on

Role of astrocyte aquaporin-4 in brain structure remodeling after traumatic brain injury: a combined MRI and STED microscopy study

ANR project accepted / Funding for Valentin Nagerl and Jérôme Badaut of 585,866 euros

Traumatic brain injury (TBI) is the first cause of disability and death in Europe among children. TBI entails significant complications for memory and sensorimotor functions several years after the initial event. These long-term effects are not only caused by local destruction of brain tissue and but also by alterations in remote brain areas, reflected in remodeled brain structure and dysregulated synaptic activity. While astrocytic aquaporin 4 (AQP4) plays a prominent role in regulating brain extracellular space and synapses, its potential involvement in the impact of TBI on remote brain areas remains unknown.

Here, we propose to study how TBI alters AQP4 expression in astrocytes, disrupts ECS, synapse morphology and behavioral and locomotor performance. We will assess the effects physical therapy on these outcomes after TBI.

We will therefore:

1) Determine the long-term impact of TBI on brain structure and behavior by using a new TBI model on P17 mice and performing a multi-scale and multi-modal analysis of brain structure and function (STED microscopy, histology, MRI, behavior) at 3 and 12 months after injury.

2) Intervene with physical therapy to improve recovery of brain structure and behavioral performance after TBI.

3) Determine the role of AQP4 during recovery from TBI by using transgenic mice, which lack AQP4.

Uniting complementary expertise in synaptic plasticity and super-resolution microscopy (Nägerl) and pathophysiology of brain injuries and MRI (Badaut), the proposed project NanoSpace will provide mechanistic insights into how the brain adapts and recovers after traumatic brain injury