The one year fate of iron oxide coated gold nanoparticles in mice

Safe implementation of nanotechnology and nanomedicine requires an in-depth understanding of the life cycle of nanoparticles in the body. Here, we investigate the long-term fate of gold/iron oxide heterostructures after intravenous injection in mice. We show these heterostructures degrade in vivo and that the magnetic and optical properties change during the degradation process. These particles eventually eliminate from the body. The comparison of two different coating shells for heterostructures, amphiphilic polymer or polyethylene glycol, reveals the long lasting impact of initial surface properties on the nanocrystal degradability and on the kinetics of elimination of magnetic iron and gold from liver and spleen. Modulation of nanoparticles reactivity to the biological environment by the choice of materials and surface functionalization may provide new directions in the design of multifunctional nanomedicines with predictable fate

Long term fate of inorganic nanoparticles in the organisme : biotransformation and biodegradation

L’avènement des nanotechnologies engendre une exposition accrue de l’homme aux nanomatériaux, représentant un risque d’un genre nouveau. A cet égard un grand nombre de recherches porte sur l’étude de leur toxicité. Néanmoins, les questions de dégradation et transformation des nanoparticules dans l’organisme sont encore peu abordées. Des études effectuées au laboratoire ont montré qu’après injection de nanoparticules d’oxyde de fer in vivo, celles-ci sont confinées dans les lysosomes où elles sont dégradées. Une partie de mes travaux de thèse se sont concentrés sur une voie possible de métabolisation des produits de dégradation issus de nanoparticules d’oxydes de fer par l’intermédiaire d’une protéine intervenant dans le métabolisme du fer, la ferritine. Nous avons élaboré plusieurs stratégies afin de détecter et de suivre le transfert de métaux vers la ferritine. Ces travaux ont permis de mettre en évidence un processus de prise en charge des produits de dégradation des nanoparticules d’oxyde de fer à l’échelle moléculaire. Une seconde partie de mes travaux ont été consacré au suivi des produits issus de la dégradation des nanoparticules d’oxyde de fer à l’échelle de l’organisme. La haute concentration endogène en fer rendant impossible ce suivi, une stratégie consistant à marquer les nanoparticules de fer avec un isotope du fer, le 57Fe, a permis de suivre les dynamiques de circulation des produits de dégradation in vivo sur une période de six mois. Nous avons également effectué un double marquage des nanoparticules, du cœur inorganique ainsi que de leur enrobage afin de caractériser leur intégrité in vivoWith the advent of nanotechnology, the exposure of humans to nanomaterials increased, representing a risk of a new kind. Although the potential toxicity of such nanomaterials is extensively studied, their long term fate, biotransformation and degradation in the organism are still poorly understood. It was demonstrated earlier in the laboratory, that after intravenous injection, iron oxide nanoparticles undergo local intracellular degradation within lysosomes. In this context, we are interested in the fate of by products from iron oxide nanoparticles. Part of my thesis has focused on a possible pathway for metabolizing these degradation products through a protein involved in iron metabolism, the ferritin. We first studied, in solution, the degradation processes of iron oxide nanoparticles in the presence of these proteins as well as the iron transfer processes from nanoparticles to ferritin. The difficulty is the high concentration of endogenous iron which makes impossible to demonstrate these in vivo transfers. Thus, we have developed a strategy, using doped iron oxide nanoparticles with a scarce element in the organism, to track these phenomena in vivo. This work highlighted a possible mechanism of biological recycling, remediation and detoxification of nanoparticles mediated by endogenous proteins at the molecular scale. A second part of my work was devoted to develop a multi-scale method to study the life cycle of metal oxide nanoparticles and their by products in organism. The main challenge is to differentiate iron stemming from the nanoparticles from the endogenous iron. This specific tracking problem is routinely encountered in geochemical studies and solved by labelling the target material with minor stable isotopes. Therefore, iron oxide nanoparticles enriched in the minor stable isotope 57Fe were synthetized and injected intravenously in mice to follow dynamic circulations of iron oxide nanoparticles and their byproducts. We have also labelled the coating to track the nanoparticles integrity in mice over a period of six mont

Cycle de vie de nanoparticules dans l'organisme : biotransformations et biodégradaton.

With the advent of nanotechnology, the exposure of humans to nanomaterials increased, representing a risk of a new kind. Although the potential toxicity of such nanomaterials is extensively studied, their long term fate, biotransformation and degradation in the organism are still poorly understood. It was demonstrated earlier in the laboratory, that after intravenous injection, iron oxide nanoparticles undergo local intracellular degradation within lysosomes. In this context, we are interested in the fate of by products from iron oxide nanoparticles. Part of my thesis has focused on a possible pathway for metabolizing these degradation products through a protein involved in iron metabolism, the ferritin. We first studied, in solution, the degradation processes of iron oxide nanoparticles in the presence of these proteins as well as the iron transfer processes from nanoparticles to ferritin. The difficulty is the high concentration of endogenous iron which makes impossible to demonstrate these in vivo transfers. Thus, we have developed a strategy, using doped iron oxide nanoparticles with a scarce element in the organism, to track these phenomena in vivo. This work highlighted a possible mechanism of biological recycling, remediation and detoxification of nanoparticles mediated by endogenous proteins at the molecular scale. A second part of my work was devoted to develop a multi-scale method to study the life cycle of metal oxide nanoparticles and their by products in organism. The main challenge is to differentiate iron stemming from the nanoparticles from the endogenous iron. This specific tracking problem is routinely encountered in geochemical studies and solved by labelling the target material with minor stable isotopes. Therefore, iron oxide nanoparticles enriched in the minor stable isotope 57Fe were synthetized and injected intravenously in mice to follow dynamic circulations of iron oxide nanoparticles and their byproducts. We have also labelled the coating to track the nanoparticles integrity in mice over a period of six monthL’avènement des nanotechnologies engendre une exposition accrue de l’homme aux nanomatériaux, représentant un risque d’un genre nouveau. A cet égard un grand nombre de recherches porte sur l’étude de leur toxicité. Néanmoins, les questions de dégradation et transformation des nanoparticules dans l’organisme sont encore peu abordées. Des études effectuées au laboratoire ont montré qu’après injection de nanoparticules d’oxyde de fer in vivo, celles-ci sont confinées dans les lysosomes où elles sont dégradées. Une partie de mes travaux de thèse se sont concentrés sur une voie possible de métabolisation des produits de dégradation issus de nanoparticules d’oxydes de fer par l’intermédiaire d’une protéine intervenant dans le métabolisme du fer, la ferritine. Nous avons élaboré plusieurs stratégies afin de détecter et de suivre le transfert de métaux vers la ferritine. Ces travaux ont permis de mettre en évidence un processus de prise en charge des produits de dégradation des nanoparticules d’oxyde de fer à l’échelle moléculaire. Une seconde partie de mes travaux ont été consacré au suivi des produits issus de la dégradation des nanoparticules d’oxyde de fer à l’échelle de l’organisme. La haute concentration endogène en fer rendant impossible ce suivi, une stratégie consistant à marquer les nanoparticules de fer avec un isotope du fer, le 57Fe, a permis de suivre les dynamiques de circulation des produits de dégradation in vivo sur une période de six mois. Nous avons également effectué un double marquage des nanoparticules, du cœur inorganique ainsi que de leur enrobage afin de caractériser leur intégrité in viv

Thinking Quantitatively of RNA-Based Information Transfer via Extracellular Vesicles: Lessons to Learn for the Design of RNA-Loaded EVs

Extracellular vesicles (EVs) are 50–1000 nm vesicles secreted by virtually any cell type in the body. They are expected to transfer information from one cell or tissue to another in a short- or long-distance way. RNA-based transfer of information via EVs at long distances is an interesting well-worn hypothesis which is ~15 years old. We review from a quantitative point of view the different facets of this hypothesis, ranging from natural RNA loading in EVs, EV pharmacokinetic modeling, EV targeting, endosomal escape and RNA delivery efficiency. Despite the unique intracellular delivery properties endowed by EVs, we show that the transfer of RNA naturally present in EVs might be limited in a physiological context and discuss the lessons we can learn from this example to design efficient RNA-loaded engineered EVs for biotherapies. We also discuss other potential EV mediated information transfer mechanisms, among which are ligand–receptor mechanisms

Nanohybrids with Magnetic and Persistent Luminescence Properties for Cell Labeling, Tracking, In Vivo Real-Time Imaging, and Magnetic Vectorization

International audienceOnce injected into a living organism, cells diffuse or migrate around the initial injection point and become impossible to be visualized and trackedin vivo. The present work concerns the development of a new technique for therapeutic cell labeling and subsequent in vivo visualization and magnetic retention. It is hypothesized and subsequently demonstrated that nanohybrids made of persistent luminescence nanoparticles and ultrasmall superparamagnetic iron oxide nanoparticles incorporated into a silica matrix can be used as an effective nanoplatform to label therapeutic cells in a nontoxic way in order to dynamically track them in real-time in vitro and in living mice. As a proof-of-concept, it is shown that once injected, these labeled cells can be visualized and attracted in vivo using a magnet. This frst step suggests that these nanohybrids represent effcient multifunctional nanoprobes for further imaging guided cell therapies development

Tailored ultra-small Prussian blue-based nanoparticles for MRI imaging and combined photothermal/photoacoustic theranostics

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Degradation of ZnGa2O4:Cr3+ luminescent nanoparticles in lysosomal-like medium

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Maghemite-nanoMIL-100(Fe) Bimodal Nanovector as a Platform for Image-Guided Therapy

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