Dynamic study of blood-brain barrier closure after its disruption using ultrasound: a quantitative analysis.

International audienceDelivery of therapeutic or diagnostic agents to the brain is majorly hindered by the blood-brain barrier (BBB). Recently, many studies have demonstrated local and transient disruption of the BBB using low power ultrasound sonication combined with intravascular microbubbles. However, BBB opening and closure mechanisms are poorly understood, especially the maximum gap that may be safely generated between endothelial cells and the duration of opening of the BBB. Here, we studied BBB opening and closure under magnetic resonance (MR) guidance in a rat model. First, MR contrast agents (CA) of different hydrodynamic diameters (1 to 65 nm) were employed to estimate the largest molecular size permissible across the cerebral tissues. Second, to estimate the duration of the BBB opening, the CA were injected at various times post-BBB disruption (12 minutes to 24 hours). A T(1) mapping strategy was developed to assess CA concentration at the ultrasound (US) focal point. Based on our experimental data and BBB closure modeling, a calibration curve was obtained to compute the half closure time as a function of CA hydrodynamic diameter. These findings and the model provide an invaluable basis for optimal design and delivery of nanoparticles to the brain

Développements de stratégies de quantification et de dispositifs expérimentaux pour l'IRM moléculaire de biomarqueurs endovasculaires et intratissulaires de pathologies cérébrales

Au cours de cette thèse, réalisée dans le cadre du projet Iseult/INUMAC, nous avons réalisé un travail de développements méthodologiques et technologiques, dans l'optique de permettre à l'IRM de devenir un outil quantitatif pour l'imagerie moléculaire de pathologies cérébrales sur des modèles rongeurs. Pour cela, nous avons développé une stratégie de quantification, utilisant des séquences de cartographie T1 et T2, pour acquérir des cartes de concentration en agents de contraste paramagnétiques et superparamagnétiques avec une excellente sensibilité, une résolution spatiale élevée, ainsi qu'une résolution temporelle compatible avec l'imagerie in vivo. La méthodologie générale que nous avons mise en place lors de ces travaux de thèse nous a permis d'aborder un certain nombre de problématiques propres à l'imagerie moléculaire de pathologies cérébrales par IRM. Dans un premier temps, nous nous sommes intéressés à l'imagerie d'un biomarqueur endovasculaire de l'angiogenèse tumorale sur un modèle de glioblastome cérébral induit chez des souris immuno-déprimées. Nous avons étudié la fixation d'une émulsion paramagnétique, fonctionnalisée par l'ajout de peptides RGD, sur l'intégrine alpha-nu-beta-3 surexprimée à la surface des cellules endothéliales de capillaires tumoraux. Nous nous sommes ensuite intéressés à la délivrance des agents de contraste aux tissus cérébraux. À l'aide d'un protocole optimisé d'ouverture de la barrière hématoencéphalique (BHE) par ultrasons focalisés sous IRM, nous avons étudié les caractéristiques de cette ouverture, ainsi que la dynamique de refermeture sur des modèles de rats et souris sains. Dans une autre étude, la mesure du coefficient de diffusion apparent d'agents de contraste dans les tissus cérébraux de rats sains nous a permis d'évaluer le temps nécessaire à ces agents de tailles différentes pour atteindre leurs cibles, une fois la BHE franchie. Ces caractéristiques représentent des informations capitales dans le cadre de la délivrance d'agents de contraste aux tissus cérébraux. Ils sont en effet susceptibles d'intéresser les industriels pharmaceutiques pour optimiser la conception d'agents diagnostiques et thérapeutiques dédiés aux pathologies cérébrales.In this thesis, which was part of the Iseult/INUMAC project, we propose several methodological and technological developments aiming to allow MRI to become a quantitative tool for molecular imaging of brain pathologies. To do so, we developed a quantification strategy based on T1 and T2 mapping sequences in order to acquire quantitative concentration maps of paramagnetic and superparamagnetic contrast agents with excellent sensitivity, high spatial resolution and temporal resolution compatible with in vivo imaging. This general methodology allowed us to address several issues specific to molecular imaging of cerebral pathologies using MRI. First, we focused on the imaging of a vascular biomarker of tumor angiogenesis on a glioblastoma mouse model. We studied the binding of a paramagnetic emulsion, functionalized using RGD peptides, on alpha-nu-beta-3 integrin over-expressed at the surface of freshly formed endothelial cells. Then, we focused on the delivery of contrast agents to brain parenchyma. A system was developed and optimized to open transiently and non-invasively rodents blood brain barrier (BBB) using focalized ultrasound monitored by MRI. The BBB opening features and closure dynamics induced by this protocol were extensively characterized. In another study, we measured the apparent diffusion coefficient of contrast agents with different sizes in cerebral tissues of healthy rats. From these measures we could estimate the time necessary for these particles to reach their targets once the BBB is crossed. These parameters are highly valuable in the context of drug delivery to the brain. They might indeed be used by pharmaceutical industries to optimize the design of diagnostic and therapeutic agents dedicated to cerebral diseases.PARIS11-SCD-Bib. électronique (914719901) / SudocSudocFranceF

Artifacts and pitfalls in diffusion MRI.

International audienceAlthough over the last 20 years diffusion MRI has become an established technique with a great impact on health care and neurosciences, like any other MRI technique it remains subject to artifacts and pitfalls. In addition to common MRI artifacts, there are specific problems that one may encounter when using MRI scanner gradient hardware for diffusion MRI, especially in terms of eddy currents and sensitivity to motion. In this article we review those artifacts and pitfalls on a qualitative basis, and introduce possible strategies that have been developed to mitigate or overcome them

Frequency-shift based detection of BMS contrast agents using SSFP: potential for MRA.

International audienceA novel mechanism of MRI contrast enhancement, based on the detection by a balanced steady-state free precession (SSFP) sequence of the proton resonance frequency shift induced by bulk magnetic susceptibility (BMS) contrast agents, was investigated. The potential for this contrast mechanism to image blood vessels was explored. The relaxation time and the frequency shift effects of gadolinium- and dysprosium-DOTA on SSFP signal was first simulated and evaluated on a water phantom at 1.5 T. In vitro, a 5-mM concentration in contrast agent induced a 20-Hz frequency shift, leading to a signal increase of 92% for Dy-DOTA, and a 10-Hz frequency shift, leading to a signal increase of 58% for Gd-DOTA at the reference frequency, taking into account the nonlinear SSFP signal response on frequency offset. The concept was then evaluated in vivo on anesthetized rabbits. Low doses of dysprosium-DOTA were injected in their vascular system, and imaging was performed at the level of neck vessels. Following a bolus injection, mean signal changes of 31%, 20% and 14% were observed in the carotid arteries, the vertebral veins and the jugular veins, respectively. The bolus peak times in arteries and veins were consistent with the rabbit vascular circulation. This frequency-shift based contrast mechanism presents interesting potential for contrast-enhanced MR angiography (CE-MRA) compared to usual relaxation-based contrast, but further investigations on reproducibility will be necessary

High temporal resolution functional MRI using parallel echo-volumar imaging

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A new paradigm for high-sensitivity 19 F magnetic resonance imaging of perfluorooctylbromide

International audienceIn the present work, the NMR properties of perfluorooctylbromide are revisited to derive a high-sensitivity fluorine MRI strategy. It is shown that the harmful effects of J-coupling can be eliminated by carefully choosing the bandwidth of the 180 degrees pulses in a spin-echo sequence. The T(2) of the CF(3) resonance of the molecule is measured using a multispin-echo sequence and shown to dramatically depend on the interpulse delay. Following these observations, an optimized multispin-echo imaging sequence is derived and compared with short TE/pulse repetition time gradient echo and chemical shift imaging sequences. The unparalleled sensitivity yielded by the multispin-echo sequence is promising for future applications, in particular for targeted contrast agents such as perfluorooctylbromide nanoparticles

In vivo CEST MR imaging of U87 mice brain tumor angiogenesis using targeted LipoCEST contrast agent at 7 T

International audienceLipoCEST are liposome-encapsulating paramagnetic contrast agents (CA) based on chemical exchange saturation transfer with applications in biomolecular MRI. Their attractive features include biocompatibility, subnanomolar sensitivity, and amenability to functionalization for targeting biomarkers. We demonstrate MR imaging using a targeted lipoCEST, injected intravenously. A lipoCEST carrying Tm(III)-complexes was conjugated to RGD tripeptide (RGD-lipoCEST), to target integrin α(ν)β(3) receptors involved in tumor angiogenesis and was compared with an unconjugated lipoCEST. Brain tumors were induced in athymic nude mice by intracerebral injection of U87MG cells and were imaged at 7 T after intravenous injection of either of the two contrast agents (n = 12 for each group). Chemical exchange saturation transfer-MSME sequence was applied over 2 h with an average acquisition time interval of 13.5 min. The chemical exchange saturation transfer signal was ∼1% in the tumor and controlateral regions, and decreased to ∼0.3% after 2 h; while RGD-lipoCEST signal was ∼1.4% in the tumor region and persisted for up to 2 h. Immunohistochemical staining revealed a persistent colocalization of RGD-lipoCEST with α(ν)β(3) receptors in the tumor region. These results constitute an encouraging step toward in vivo MRI imaging of tumor angiogenesis using intravenously injected lipoCEST

Evaluation of saliva as a source of accurate wholegenome and microbiome sequencing data

International audienceThis study sets out to establish the suitability of saliva-based whole-genome sequencing (WGS) through a comparison against blood-based WGS. To fully appraise the observed differences, we developed a novel technique of pseudo-replication. We also investigated the potential of characterising individual salivary microbiomes from non-human DNA fragments found in saliva. We observed that the majority of discordant genotype calls between blood and saliva fell into known regions of the human genome that are typically sequenced with low confidence; and could be identified by quality control measures. Pseudo-replication demonstrated that the levels of discordance between blood-and saliva-derived WGS data were entirely similar to what one would expect between technical replicates if an individual's blood or saliva had been sequenced twice. Finally, we successfully sequenced salivary microbiomes in parallel to human genomes as demonstrated by a comparison against the Human Microbiome Project