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Interdisciplinary PhD position (Fluid Dynamics / Ecophysiology) (M/F)

Ente di ricercaScadenza 31 luglio 2026
Ente
CNRS
Paese
Francia
Campo di ricerca
Engineering Chemistry Physics
Lingua dell’annuncio
Inglese
Tipo di contratto
Temporary
Profilo ricercato
Ricercatore universitario
Titolo di studio
Master Degree or equivalent
Sede
TOULOUSE, Francia
Pubblicato il
Scadenza
31 luglio 2026

Descrizione

Interdisciplinary PhD position (Fluid Dynamics / Ecophysiology) (M/F) Sintesi in italiano (traduzione automatica): L'ente offre una posizione di dottorato interdisciplinare in Fluidodinamica ed Ecofisiologia, con sede presso l'Istituto di Meccanica dei Fluidi di Tolosa e il Centro di Studi Biologici di Chizé. Il progetto di ricerca si concentra sull'adattamento del cervello all'ipossia nei foche elefante meridionali, esplorando le capacità evolutive di questi mammiferi marini. Le mansioni principali includono l'analisi delle proprietà architettoniche delle reti microvascolari nel cervello e l'uso di modelli teorici e numerici per studiare il flusso sanguigno e il trasporto di ossigeno. È richiesta una laurea in Biologia, Fisica o Ingegneria, con competenze in modellazione e analisi dei dati. This thesis project is part of a collaboration between two teams developing complementary approaches. The “Porous and Biological Media” group at the Toulouse Institute of Fluid Mechanics is a pioneer in multiscale modeling of cerebral blood microcirculation and its role in neurodegenerative diseases. The Chizé Center for Biological Studies possesses world-class expertise in the adaptation of marine mammals to environmental stressors (ecophysiology), particularly thanks to its privileged access to the Dumont-d'Urville Antarctic station. Title : Adaptation of the Brain to Hypoxia in the Southern Elephant Seal Scientific context and hypothesis: The mammalian brain is the organ with the highest basal energy demand. It is therefore extremely vulnerable 1) to sudden interruptions in the blood's oxygen supply, which can cause neuronal death within minutes with devastating consequences, or 2) to chronic cerebral hypoperfusion or hypoxia (oxygen deprivation), which lead to neurodegeneration and cognitive decline (vascular dementias, etc.). In this context, IMFT has recently shown that the intrinsic heterogeneity of the cerebral microvascular system, and of the associated blood flow and transport processes, causes the emergence of microregions with low oxygen levels in brain tissue, primarily located in subcortical areas, even when perfusion is normal [1]. The greater this heterogeneity, the less the vascular system can withstand additional stress (e.g., capillary occlusions, vascular rarefaction, and/or hypoperfusion, which are typically observed in aging and many pathologies). This finding suggests that, under stress, the microvascular system may activate compensatory mechanisms (e.g., short-term vasoreactivity and/or chronic remodeling of cerebral vessels) that allow it to reduce this heterogeneity. To explore this hypothesis, we will use a marine mammal model that has developed exceptional evolutionary capabilities for resistance to hypoxia: the southern elephant seals (EM), Mirounga leonina, which dive to depths of 400 to 1,000 m for durations ranging from 30 minutes to 2 hours (vs. the common seal (PC), Phoca vitulina, 20 m, 10 to 20 minutes) [2,3], whose cerebrovascular system the CEBC has begun to study under natural conditions (field campaigns in Kerguelen), revealing an increase in the density and tortuosity of cerebral capillaries with age, linked to a shift in lifestyle: terrestrial (juveniles) to marine (adults) [3]. We therefore hypothesize that this phenotypic change in cerebral vessels is sufficient to reduce the intrinsic heterogeneity of blood flow and microvascular transport processes, thereby enabling the maintenance of neuronal oxygenation during phases of diving-associated hypoxia. Objectives: The first objective is therefore to quantitatively explore the variability in the architectural properties of microvascular networks across brain regions (cortex, cerebellum, and hypothalamus) and over the course of a lifetime in EM and PC, as well as the correlations between this variability and the level of exposure to hypoxia. In fact, the EM lives on land for up to 8 weeks after birth, and then goes on to make a series of dives (averaging 30 minutes), with severe arterial hypoxia in experienced adults at the end of a dive (PAO₂ ~3 mmHg), which still maintain their cognitive functions. The second objective is to use theoretical and numerical modeling approaches of microvascular blood flow and oxygen transport to study the impact of this variability on the heterogeneity of blood flow and transport. If the above hypothesis is valid, we can indeed expect: 1) an initial phase during which morphological and topological changes in the vascular system would lead to a decrease in this heterogeneity during development in EM, much more markedly than in PC; and 2) by analogy with clinical knowledge in humans [4], beyond a certain level of accumulated stress, a collapse of these adaptive capacities, leading to premature aging, which m Annuncio in inglese. Fonte: Euraxess (Commissione europea).

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